TY - JOUR
A1 - Pelisoli, Ingrid
A1 - Dorsch, Matti
A1 - Heber, Ulrich
A1 - Gänsicke, Boris
A1 - Geier, Stephan
A1 - Kupfer, Thomas
A1 - Nemeth, Peter
A1 - Scaringi, Simone
A1 - Schaffenroth, Veronika
T1 - Discovery and analysis of three magnetic hot subdwarf stars
BT - evidence for merger-induced magnetic fields
JF - Monthly notices of the Royal Astronomical Society
N2 - Magnetic fields can play an important role in stellar evolution. Among white dwarfs, the most common stellar remnant, the fraction of magnetic systems is more than 20 per cent. The origin of magnetic fields in white dwarfs, which show strengths ranging from 40 kG to hundreds of MG, is still a topic of debate. In contrast, only one magnetic hot subdwarf star has been identified out of thousands of known systems. Hot subdwarfs are formed from binary interaction, a process often associated with the generation of magnetic fields, and will evolve to become white dwarfs, which makes the lack of detected magnetic hot subdwarfs a puzzling phenomenon. Here we report the discovery of three new magnetic hot subdwarfs with field strengths in the range 300-500 kG. Like the only previously known system, they are all helium-rich O-type stars (He-sdOs). We analysed multiple archival spectra of the three systems and derived their stellar properties. We find that they all lack radial velocity variability, suggesting formation via a merger channel. However, we derive higher than typical hydrogen abundances for their spectral type, which are in disagreement with current model predictions. Our findings suggest a lower limit to the magnetic fraction of hot subdwarfs of 0.147(+0.143)(-0.047) per cent, and provide evidence for merger-induced magnetic fields which could explain white dwarfs with field strengths of 50-150 MG, assuming magnetic flux conservation.
KW - stars: magnetic field
KW - subdwarfs
Y1 - 2022
U6 - https://doi.org/10.1093/mnras/stac1069
SN - 0035-8711
SN - 1365-2966
VL - 515
IS - 2
SP - 2496
EP - 2510
PB - Oxford University Press
CY - Oxford
ER -
TY - GEN
A1 - Mattern, Maximilian
A1 - Pudell, Jan-Etienne
A1 - Dumesnil, Karine
A1 - Reppert, Alexander von
A1 - Bargheer, Matias
T1 - Towards shaping picosecond strain pulses via magnetostrictive transducers
T2 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2 - Using time-resolved x-ray diffraction, we demonstrate the manipulation of the picosecond strain response of a metallic heterostructure consisting of a dysprosium (Dy) transducer and a niobium (Nb) detection layer by an external magnetic field. We utilize the first-order ferromagnetic–antiferromagnetic phase transition of the Dy layer, which provides an additional large contractive stress upon laser excitation compared to its zerofield response. This enhances the laser-induced contraction of the transducer and changes the shape of the picosecond strain pulses driven in Dy and detected within the buried Nb layer. Based on our experiment with rare-earth metals we discuss required properties for functional transducers, which may allow for novel field-control of the emitted picosecond strain pulses.
T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1321
KW - picosecond ultrasonics
KW - magnetostriction
KW - ultrafast x-ray diffraction
KW - ultrafast photoacoustics
KW - nanoscale heat transfer
KW - negative thermal expansion
Y1 - 2023
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-588868
SN - 1866-8372
IS - 1321
ER -
TY - JOUR
A1 - Saikin, Anthony
A1 - Shprits, Yuri Y.
A1 - Drozdov, Alexander
A1 - Landis, Daji August
A1 - Zhelavskaya, Irina
A1 - Cervantes Villa, Juan Sebastian
T1 - Reconstruction of the radiation belts for solar cycles 17-24 (1933-2017)
JF - Space weather : the international journal of research and applications
N2 - We present a reconstruction of the dynamics of the radiation belts from solar cycles 17 to 24 which allows us to study how radiation belt activity has varied between the different solar cycles. The radiation belt simulations are produced using the Versatile Electron Radiation Belt (VERB)-3D code. The VERB-3D code simulations incorporate radial, energy, and pitch angle diffusion to reproduce the radiation belts. Our simulations use the historical measurements of Kp (available since solar cycle 17, i.e., 1933) to model the evolution radiation belt dynamics between L* = 1-6.6. A nonlinear auto regressive network with exogenous inputs (NARX) neural network was trained off GOES 15 measurements (January 2011-March 2014) and used to supply the upper boundary condition (L* = 6.6) over the course of solar cycles 17-24 (i.e., 1933-2017). Comparison of the model with long term observations of the Van Allen Probes and CRRES demonstrates that our model, driven by the NARX boundary, can reconstruct the general evolution of the radiation belt fluxes. Solar cycle 24 (January 2008-2017) has been the least active of the considered solar cycles which resulted in unusually low electron fluxes. Our results show that solar cycle 24 should not be used as a representative solar cycle for developing long term environment models. The developed reconstruction of fluxes can be used to develop or improve empirical models of the radiation belts.
Y1 - 2021
U6 - https://doi.org/10.1029/2020SW002524
SN - 1542-7390
VL - 19
IS - 3
PB - Wiley
CY - New York
ER -
TY - JOUR
A1 - Mattern, Maximilian
A1 - Reppert, Alexander von
A1 - Zeuschner, Steffen Peer
A1 - Herzog, Marc
A1 - Pudell, Jan-Etienne
A1 - Bargheer, Matias
T1 - Concepts and use cases for picosecond ultrasonics with x-rays
JF - Photoacoustics
N2 - This review discusses picosecond ultrasonics experiments using ultrashort hard x-ray probe pulses to extract the transient strain response of laser-excited nanoscopic structures from Bragg-peak shifts. This method provides direct, layer-specific, and quantitative information on the picosecond strain response for structures down to few-nm thickness. We model the transient strain using the elastic wave equation and express the driving stress using Gruneisen parameters stating that the laser-induced stress is proportional to energy density changes in the microscopic subsystems of the solid, i.e., electrons, phonons and spins. The laser-driven strain response can thus serve as an ultrafast proxy for local energy-density and temperature changes, but we emphasize the importance of the nanoscale morphology for an accurate interpretation due to the Poisson effect. The presented experimental use cases encompass ultrathin and opaque metal-heterostructures, continuous and granular nanolayers as well as negative thermal expansion materials, that each pose a challenge to established all-optical techniques.
KW - Picosecond ultrasonics
KW - Ultrafast x-ray diffraction
KW - Ultrafast x-ray
KW - scattering
KW - Ultrafast photoacoustics
KW - Nanoscale heat transfer
KW - Negative
KW - thermal expansion
Y1 - 2023
U6 - https://doi.org/10.1016/j.pacs.2023.100503
SN - 2213-5979
VL - 31
PB - Elsevier
CY - Amsterdam
ER -
TY - JOUR
A1 - Vilk, Ohad
A1 - Aghion, Erez
A1 - Avgar, Tal
A1 - Beta, Carsten
A1 - Nagel, Oliver
A1 - Sabri, Adal
A1 - Sarfati, Raphael
A1 - Schwartz, Daniel K.
A1 - Weiß, Matthias
A1 - Krapf, Diego
A1 - Nathan, Ran
A1 - Metzler, Ralf
A1 - Assaf, Michael
T1 - Unravelling the origins of anomalous diffusion
BT - from molecules to migrating storks
JF - Physical review research / American Physical Society
N2 - Anomalous diffusion or, more generally, anomalous transport, with nonlinear dependence of the mean-squared displacement on the measurement time, is ubiquitous in nature. It has been observed in processes ranging from microscopic movement of molecules to macroscopic, large-scale paths of migrating birds. Using data from multiple empirical systems, spanning 12 orders of magnitude in length and 8 orders of magnitude in time, we employ a method to detect the individual underlying origins of anomalous diffusion and transport in the data. This method decomposes anomalous transport into three primary effects: long-range correlations (“Joseph effect”), fat-tailed probability density of increments (“Noah effect”), and nonstationarity (“Moses effect”). We show that such a decomposition of real-life data allows us to infer nontrivial behavioral predictions and to resolve open questions in the fields of single-particle tracking in living cells and movement ecology.
Y1 - 2022
U6 - https://doi.org/10.1103/PhysRevResearch.4.033055
SN - 2643-1564
VL - 4
IS - 3
PB - American Physical Society
CY - College Park, MD
ER -
TY - THES
A1 - Cervantes Villa, Juan Sebastian
T1 - Understanding the dynamics of radiation belt electrons by means of data assimilation
T1 - Verständnis der Dynamik von Strahlungsgürtel-Elektronen durch Datenassimilation
N2 - The Earth's electron radiation belts exhibit a two-zone structure, with the outer belt being highly dynamic due to the constant competition between a number of physical processes, including acceleration, loss, and transport. The flux of electrons in the outer belt can vary over several orders of magnitude, reaching levels that may disrupt satellite operations. Therefore, understanding the mechanisms that drive these variations is of high interest to the scientific community.
In particular, the important role played by loss mechanisms in controlling relativistic electron dynamics has become increasingly clear in recent years. It is now widely accepted that radiation belt electrons can be lost either by precipitation into the atmosphere or by transport across the magnetopause, called magnetopause shadowing. Precipitation of electrons occurs due to pitch-angle scattering by resonant interaction with various types of waves, including whistler mode chorus, plasmaspheric hiss, and electromagnetic ion cyclotron waves. In addition, the compression of the magnetopause due to increases in solar wind dynamic pressure can substantially deplete electrons at high L shells where they find themselves in open drift paths, whereas electrons at low L shells can be lost through outward radial diffusion. Nevertheless, the role played by each physical process during electron flux dropouts still remains a fundamental puzzle.
Differentiation between these processes and quantification of their relative contributions to the evolution of radiation belt electrons requires high-resolution profiles of phase space density (PSD). However, such profiles of PSD are difficult to obtain due to restrictions of spacecraft observations to a single measurement in space and time, which is also compounded by the inaccuracy of instruments. Data assimilation techniques aim to blend incomplete and inaccurate spaceborne data with physics-based models in an optimal way. In the Earth's radiation belts, it is used to reconstruct the entire radial profile of electron PSD, and it has become an increasingly important tool in validating our current understanding of radiation belt dynamics, identifying new physical processes, and predicting the near-Earth hazardous radiation environment.
In this study, sparse measurements from Van Allen Probes A and B and Geostationary Operational Environmental Satellites (GOES) 13 and 15 are assimilated into the three-dimensional Versatile Electron Radiation Belt (VERB-3D) diffusion model, by means of a split-operator Kalman filter over a four-year period from 01 October 2012 to 01 October 2016. In comparison to previous works, the 3D model accounts for more physical processes, namely mixed pitch angle-energy diffusion, scattering by EMIC waves, and magnetopause shadowing. It is shown how data assimilation, by means of the innovation vector (the residual between observations and model forecast), can be used to account for missing physics in the model. This method is used to identify the radial distances from the Earth and the geomagnetic conditions where the model is inconsistent with the measured PSD for different values of the adiabatic invariants mu and K. As a result, the Kalman filter adjusts the predictions in order to match the observations, and this is interpreted as evidence of where and when additional source or loss processes are active.
Furthermore, two distinct loss mechanisms responsible for the rapid dropouts of radiation belt electrons are investigated: EMIC wave-induced scattering and magnetopause shadowing. The innovation vector is inspected for values of the invariant mu ranging from 300 to 3000 MeV/G, and a statistical analysis is performed to quantitatively assess the effect of both processes as a function of various geomagnetic indices, solar wind parameters, and radial distance from the Earth. The results of this work are in agreement with previous studies that demonstrated the energy dependence of these two mechanisms. EMIC wave scattering dominates loss at lower L shells and it may amount to between 10%/hr to 30%/hr of the maximum value of PSD over all L shells for fixed first and second adiabatic invariants. On the other hand, magnetopause shadowing is found to deplete electrons across all energies, mostly at higher L shells, resulting in loss from 50%/hr to 70%/hr of the maximum PSD. Nevertheless, during times of enhanced geomagnetic activity, both processes can operate beyond such location and encompass the entire outer radiation belt.
The results of this study are two-fold. Firstly, it demonstrates that the 3D data assimilative code provides a comprehensive picture of the radiation belts and is an important step toward performing reanalysis using observations from current and future missions. Secondly, it achieves a better understanding and provides critical clues of the dominant loss mechanisms responsible for the rapid dropouts of electrons at different locations over the outer radiation belt.
N2 - Die Elektronenstrahlungsgürtel der Erde weisen eine Zwei-Zonen-Struktur auf, wobei der äußere Gürtel aufgrund des ständigen Zusammenspiels zwischen einer Reihe von physikalischen Prozessen, einschließlich Beschleunigung, Verlust und Transport, eine hohe Dynamik aufweist. Der Elektronenfluss im äußeren Gürtel kann über mehrere Größenordnungen variieren und Werte erreichen, die den Satellitenbetrieb stören können. Daher ist das Verständnis der Mechanismen, die diese Variabilität bewirken, von hohem Interesse für die wissenschaftliche Gemeinschaft.
Insbesondere die wichtige Rolle die Verlustmechanismen bei der Kontrolle der relativistischen Elektronendynamik spielen ist in den letzten Jahren immer deutlicher geworden. Es ist inzwischen weithin anerkannt, dass Strahlungsgürtelelektronen entweder durch Interaktion mit der Atmosphäre oder durch Transport über die Magnetopause, das so genannte Magnetopauseshadowing, verloren gehen können. Der Verlust von Elektronen in der Atmosphäre erfolgt aufgrund von Pitchwinkelstreuung durch resonante Wechselwirkung mit verschiedenen Arten von magnetosphärischen Wellen, einschließlich plasmasphärischem Hiss, Whistler-Mode-Chorus, und elektromagnetischen Ionenzyklotron-Wellen (EMIC). Darüber hinaus kann die Komprimierung der Magnetopause aufgrund der Erhöhungen des dynamischen Drucks des Sonnenwindes dazu führen, dass Elektronen an hohen L-Shells, wo sie sich in offenen Driftpfaden befinden, erheblich in ihrer Dichte reduziert werden, während Elektronen an niedrigen L-Shells durch radiale Diffusion nach außen verloren gehen können. Nichtsdestotrotz bleibt die Rolle, die jeder physikalische Prozess bei der schnellen Reduktion des Elektronenflusses spielt, nach wie vor ein grundlegendes Rätsel.
Die Unterscheidung zwischen diesen Prozessen und die Quantifizierung ihrer relativen Beiträge zur Entwicklung der Strahlungsgürtelelektronen erfordert hochauflösende Profile der Phasenraumdichte (PSD). Solche Profile der PSD sind jedoch schwierig zu bestimmen, da die Beobachtungen von Raumfahrzeugen auf eine einzige Messung in Raum und Zeit beschränkt sind, was auch durch die Ungenauigkeit der Instrumente erschwert wird. Datenassimilationstechniken zielen darauf ab, unvollständige und ungenaue raumgestützte Daten mit physikalisch basierten Modellen auf optimale Weise zu kombinieren. In den Strahlungsgürteln der Erde werden sie verwendet, um das gesamte radiale Profil der Elektronen-PSD zu rekonstruieren, und sie sind zu einem immer wichtigeren Werkzeug geworden, um unser derzeitiges Verständnis der Dynamik der Strahlungsgürtel zu validieren, neue physikalische Prozesse zu identifizieren und die erdnahe gefährliche Strahlungsumgebung vorherzusagen.
In dieser Studie werden Messungen der Van-Allen-Probes A und B und der Geostationary-Operational-Environmental-Satellites (GOES) 13 und 15 mit Hilfe eines Split-Operator-Kalman-Filters über einen Zeitraum von vier Jahren vom 01. Oktober 2012 bis zum 01. Oktober 2016 in das dreidimensionale Versatile Electron Radiation Belt-3D-Diffusionsmodell (VERB-3D) integriert. Im Vergleich zu früheren Arbeiten berücksichtigt das 3D-Modell mehr physikalische Prozesse, nämlich gemischte Diffusion, Streuung durch EMIC-Wellen und Magnetopausenverluste. Es wird gezeigt, wie die Datenassimilation mit Hilfe des Innovationsvektors (des Residuums zwischen Beobachtungen und Modellprognose), genutzt werden kann, um fehlende physikalische Prozesse im Modell zu berücksichtigen. Diese Methode wird verwendet, um die radialen Entfernungen von der Erde und die geomagnetischen Bedingungen zu identifizieren, bei denen unser Modell für verschiedene Werte der adiabatischen Invarianten mu und K nicht mit der gemessenen PSD übereinstimmt. Infolgedessen passt der Kalman-Filter die Vorhersagen an die Beobachtungen an, und dies wird als Nachweis dafür interpretiert, wo und wann zusätzliche Quellen- oder Verlustprozesse aktiv sind.
Darüber hinaus werden zwei unterschiedliche Verlustmechanismen untersucht, die für die schnellen Verluste von Strahlungsgürtelelektronen verantwortlich sind: EMIC-Wellen-induzierte Streuung und Magnetopausenverluste. Der Innovationsvektor wird bei Werten der Invariante mu im Bereich von 300 bis 3000 MeV/G untersucht, und es wird eine statistische Analyse durchgeführt, um die Wirkung beider Prozesse in Abhängigkeit von verschiedenen geomagnetischen Indizes, Sonnenwindparametern und der radialen Entfernung von der Erde quantitativ zu bewerten. Die Ergebnisse dieser Arbeit stehen in Übereinstimmung mit früheren Studien, die die Energieabhängigkeit dieser beiden Mechanismen nachgewiesen haben. Die EMIC-Wellenstreuung dominiert den Verlust bei niedrigen L-Shells und kann zwi-schen 10%/hr bis 30%/hr des Maximalwertes der PSD über alle L-Shells für feste Werte der ersten und zweiten adiabatische Invarianten betragen. Andererseits wird festgestellt, dass bei den Magnetopausenverlusten über alle Energien hinweg, meist bei höheren L-Shells, Elektronen Verluste zeigen, was zu einer Verstärkung des Verlustes von 50%/hr auf 70%/hr der maximalen PSD führt. Nichtsdestotrotz können beide Prozesse in Zeiten erhöhter geomagnetischer Aktivität über diese L-Shells hinaus wirken und den gesamten äußeren Strahlungsgürtel umfassen.
Die Ergebnisse dieser Studie sind zweifacher Art. Erstens zeigt sie, dass der 3D-Daten-Assimilationscode ein umfassendes Bild der Strahlungsgürtel liefert und ein wichtiger Schritt zur Durchführung einer Reanalyse unter Verwendung von Beobachtungen aus aktuellen und zukünftigen Missionen ist. Zweitens erreicht er ein besseres Verständnis und liefert entscheidende Hinweise auf die vorherrschenden Verlustmechanismen, die für die schnellen Verluste von Elektronen an verschiedenen Orten im äußeren Strahlungsgürtel verantwortlich sind.
KW - radiation belts
KW - Strahlungsgürtel
KW - data assimilation
KW - Datenassimilation
KW - phase space density
KW - Phasenraumdichte
KW - magnetospheric waves
KW - magnetosphärischen Wellen
KW - Kalman filter
KW - Kalman-Filter
Y1 - 2021
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-519827
ER -
TY - GEN
A1 - Mattern, Maximilian
A1 - Pudell, Jan-Etienne
A1 - Laskin, G.
A1 - Reppert, Alexander von
A1 - Bargheer, Matias
T1 - Analysis of the temperature- and fluence-dependent magnetic stress in laser-excited SrRuO3
T2 - Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2 - We use ultrafast x-ray diffraction to investigate the effect of expansive phononic and contractive magnetic stress driving the picosecond strain response of a metallic perovskite SrRuO3 thin film upon femtosecond laser excitation. We exemplify how the anisotropic bulk equilibrium thermal expansion can be used to predict the response of the thin film to ultrafast deposition of energy. It is key to consider that the laterally homogeneous laser excitation changes the strain response compared to the near-equilibrium thermal expansion because the balanced in-plane stresses suppress the Poisson stress on the picosecond timescale. We find a very large negative Grüneisen constant describing the large contractive stress imposed by a small amount of energy in the spin system. The temperature and fluence dependence of the strain response for a double-pulse excitation scheme demonstrates the saturation of the magnetic stress in the high-fluence regime.
T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1144
KW - Thin films
KW - Thermodynamic properties
KW - Bragg peak
KW - Ultrafast X-ray diffraction
KW - Thermal effects
KW - Phonons
KW - Magnetism
KW - Lattice dynamics
KW - Lasers
KW - Perovskites
Y1 - 2021
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-515718
SN - 1866-8372
ER -
TY - THES
A1 - Reppert, Alexander von
T1 - Magnetic strain contributions in laser-excited metals studied by time-resolved X-ray diffraction
T1 - Untersuchung magnetischer Beiträge zur Ausdehnung laserangeregter Metalle mittels zeitaufgelöster Röntgenbeugungsexperimente
N2 - In this work I explore the impact of magnetic order on the laser-induced ultrafast strain response of metals. Few experiments with femto- or picosecond time-resolution have so far investigated magnetic stresses. This is contrasted by the industrial usage of magnetic invar materials or magnetostrictive transducers for ultrasound generation, which already utilize magnetostrictive stresses in the low frequency regime.
In the reported experiments I investigate how the energy deposition by the absorption of femtosecond laser pulses in thin metal films leads to an ultrafast stress generation. I utilize that this stress drives an expansion that emits nanoscopic strain pulses, so called hypersound, into adjacent layers. Both the expansion and the strain pulses change the average inter-atomic distance in the sample, which can be tracked with sub-picosecond time resolution using an X-ray diffraction setup at a laser-driven Plasma X-ray source. Ultrafast X-ray diffraction can also be applied to buried layers within heterostructures that cannot be accessed by optical methods, which exhibit a limited penetration into metals. The reconstruction of the initial energy transfer processes from the shape of the strain pulse in buried detection layers represents a contribution of this work to the field of picosecond ultrasonics.
A central point for the analysis of the experiments is the direct link between the deposited energy density in the nano-structures and the resulting stress on the crystal lattice. The underlying thermodynamical concept of a Grüneisen parameter provides the theoretical framework for my work. I demonstrate how the Grüneisen principle can be used for the interpretation of the strain response on ultrafast timescales in various materials and that it can be extended to describe magnetic stresses. The class of heavy rare-earth elements exhibits especially large magnetostriction effects, which can even lead to an unconventional contraction of the laser-excited transducer material. Such a dominant contribution of the magnetic stress to the motion of atoms has not been demonstrated previously. The observed rise time of the magnetic stress contribution in Dysprosium is identical to the decrease in the helical spin-order, that has been found previously using time-resolved resonant X-ray diffraction. This indicates that the strength of the magnetic stress can be used as a proxy of the underlying magnetic order. Such magnetostriction measurements are applicable even in case of antiparallel or non-collinear alignment of the magnetic moments and a vanishing magnetization.
The strain response of metal films is usually determined by the pressure of electrons and lattice vibrations. I have developed a versatile two-pulse excitation routine that can be used to extract the magnetic contribution to the strain response even if systematic measurements above and below the magnetic ordering temperature are not feasible. A first laser pulse leads to a partial ultrafast demagnetization so that the amplitude and shape of the strain response triggered by the second pulse depends on the remaining magnetic order. With this method I could identify a strongly anisotropic magnetic stress contribution in the magnetic data storage material iron-platinum and identify the recovery of the magnetic order by the variation of the pulse-to-pulse delay. The stark contrast of the expansion of iron-platinum nanograins and thin films shows that the different constraints for the in-plane expansion have a strong influence on the out-of-plane expansion, due to the Poisson effect. I show how such transverse strain contributions need to be accounted for when interpreting the ultrafast out-of-plane strain response using thermal expansion coefficients obtained in near equilibrium conditions.
This work contributes an investigation of magnetostriction on ultrafast timescales to the literature of magnetic effects in materials. It develops a method to extract spatial and temporal varying stress contributions based on a model for the amplitude and shape of the emitted strain pulses. Energy transfer processes result in a change of the stress profile with respect to the initial absorption of the laser pulses. One interesting example occurs in nanoscopic gold-nickel heterostructures, where excited electrons rapidly transport energy into a distant nickel layer, that takes up much more energy and expands faster and stronger than the laser-excited gold capping layer. Magnetic excitations in rare earth materials represent a large energy reservoir that delays the energy transfer into adjacent layers. Such magneto-caloric effects are known in thermodynamics but not extensively covered on ultrafast timescales. The combination of ultrafast X-ray diffraction and time-resolved techniques with direct access to the magnetization has a large potential to uncover and quantify such energy transfer processes.
N2 - In dieser Arbeit untersuche ich den Einfluss magnetischer Ordnung auf die laser-induzierte, ultraschnelle Ausdehnung von Metallen. In Experimenten mit Femto- oder Pikosekunden Zeitauflösung sind magnetische Drücke bisher kaum erforscht. Dies steht im Kontrast zur industriellen Verwendung von magnetischen Invar Materialien oder magnetostriktiven Ultraschallgebern, in denen magnetische Drücke bereits in niedrigeren Frequenzbereichen Anwendung finden.
In meinen Experimenten untersuche ich, wie der Energieeintrag durch die Absorption von Femtosekunden-Laserpulsen in dünnen Metallschichten zu einem ultraschnellen Druckanstieg führt. Dabei nutze ich, dass der Druckanstieg zu einer Ausdehnung führt, welche Deformationswellen auf der Nanometerskala, sogenannte Hyperschallpulse, in angrenzende Schichten aussendet. Sowohl die Ausdehnung als auch die Deformationspulse ändern den mittleren Abstand zwischen den Atomen in der Probe, welcher mittels Röntgenbeugung an einer Laser-getriebenen Plasma-Röntgenquelle mit einer Subpikosekunden-Zeitauflösung detektiert wird. Das Verfahren der ultraschnellen Röntgenbeugung gelingt auch in Heterostrukturen mit vergrabenen Detektionsschichten, zu denen optische Methoden aufgrund ihrer limitierter Eindringtiefe in Metallen keinen Zugang haben. Ein Beitrag dieser Arbeit zum Feld der Pikosekunden-Akustik ist es, aus der Ausdehnung einer solchen Detektionsschicht Rückschlüsse auf die initialen Energietransferprozesse zu ziehen.
Der direkte Zusammenhang zwischen der eingebrachten Energiedichte in die Nanostrukturen und dem resultierenden Druck auf das Atomgitter ist ein zentraler Punkt in meiner Analyse der Experimente. Das zu Grunde liegende thermodynamische Konzept des Grüneisen-Parameters bildet den theoretischen Kontext meiner Publikationen. Anhand verschiedener Materialien demonstriere ich, wie dieses Prinzip auch zur Analyse der Ausdehnung auf ultraschnellen Zeitskalen verwendet werden kann und sich auch auf magnetische Drücke übertragen lässt. Insbesondere in der Materialklasse der schweren, seltenen Erdelemente sind Magnetostriktionseffekte sehr groß und führen dort sogar zu einem ungewöhnlichen Zusammenziehen des Materials nach der Laseranregung. Solch ein bestimmender Einfluss des magnetischen Drucks auf die Atombewegung ist bisher nicht gezeigt worden. Die Zeitskala des magnetischen Druckanstiegs entspricht dabei der beobachteten Abnahme der helikalen Spin-Ordnung, welche zuvor mittels zeitaufgelöster, resonanter Röntgenbeugung ermittelt wurde. Dies zeigt, dass die Stärke des magnetischen Drucks als Maß für magnetische Ordnung dienen kann, insbesondere auch im Fall von antiparalleler oder nicht-kollinearer Ordnung der magnetischen Momente in Proben mit verschwindender Magnetisierung.
In Metallfilmen ist die Dehnung des Atomgitters in der Regel durch Druck von Elektronen und Gitterschwingungen geprägt. Um den magnetischen Druckbeitrag auch in solchen Fällen zu extrahieren, in denen systematische Experimente oberhalb und unterhalb der magnetischen Ordnungstemperatur nicht praktikabel sind, habe ich ein neuartiges Doppelpuls-Anregungsverfahren entwickelt, welches allgemein für die Untersuchung von Phasenübergängen nützlich ist. Der Energieeintrag durch den ersten Laserpuls führt dabei zu einer partiellen, ultraschnellen Demagnetisierung, sodass die Amplitude und Form der Gitterausdehnung nach dem zweiten Puls von der Stärke des verbliebenen magnetischen Drucks und somit von der verbliebenen magnetischen Ordnung abhängt. Mit dieser Methode ist es möglich geworden, einen stark richtungsabhängigen, magnetischen Druckbeitrag im Speichermedium Eisen-Platin zu identifizieren und mittels Variation des Puls-zu-Puls Abstands auch die Rückkehr der magnetischen Ordnung zu zeigen. Die unterschiedliche Ausdehnung von Eisen-Platin Nanopartikeln und dünnen Filmen zeigt dabei, dass die verschiedenen Zwangsbedingungen für die Ausdehnung entlang der Probenoberfläche aufgrund des Poisson-Effekts einen entscheidenden Einfluss auf die ultraschnelle Ausdehnung senkrecht zur Probenoberfläche hat. Ich analysiere, wie die zugrunde liegende Querkontraktion bei der Interpretation der ultraschnellen Ausdehnung auf der Basis von thermischen Ausdehnungskoeffizienten im Quasi-Gleichgewicht berücksichtigt werden kann.
Meine Arbeit erweitert die Literatur um einen Beitrag zur ultraschnellen Magnetostriktion und entwickelt eine Methodik mittels derer räumlich und zeitlich variierende Druckbeiträge anhand einer Modellierung der Form der Deformationswellen extrahiert werden können. Energietransferprozesse spiegeln sich dabei durch eine Änderung des Druckprofils gegenüber dem Absorptionsprofil der Laserpulse wider.
KW - lattice dynamics
KW - magnetism
KW - ultrafast
KW - X-ray diffraction
KW - Gitterdynamik
KW - Magnetismus
KW - ultraschnell
KW - Röntgenbeugung
Y1 - 2021
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-535582
ER -
TY - GEN
A1 - Stolterfoht, Martin
A1 - Grischek, Max
A1 - Caprioglio, Pietro
A1 - Wolff, Christian Michael
A1 - Gutierrez-Partida, Emilio
A1 - Peña-Camargo, Francisco
A1 - Rothhardt, Daniel
A1 - Zhang, Shanshan
A1 - Raoufi, Meysam
A1 - Wolansky, Jakob
A1 - Abdi-Jalebi, Mojtaba
A1 - Stranks, Samuel D.
A1 - Albrecht, Steve
A1 - Kirchartz, Thomas
A1 - Neher, Dieter
T1 - How to quantify the efficiency potential of neat perovskite films
BT - Perovskite semiconductors with an implied efficiency exceeding 28%
T2 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2 - Perovskite photovoltaic (PV) cells have demonstrated power conversion efficiencies (PCE) that are close to those of monocrystalline silicon cells; however, in contrast to silicon PV, perovskites are not limited by Auger recombination under 1-sun illumination. Nevertheless, compared to GaAs and monocrystalline silicon PV, perovskite cells have significantly lower fill factors due to a combination of resistive and non-radiative recombination losses. This necessitates a deeper understanding of the underlying loss mechanisms and in particular the ideality factor of the cell. By measuring the intensity dependence of the external open-circuit voltage and the internal quasi-Fermi level splitting (QFLS), the transport resistance-free efficiency of the complete cell as well as the efficiency potential of any neat perovskite film with or without attached transport layers are quantified. Moreover, intensity-dependent QFLS measurements on different perovskite compositions allows for disentangling of the impact of the interfaces and the perovskite surface on the non-radiative fill factor and open-circuit voltage loss. It is found that potassium-passivated triple cation perovskite films stand out by their exceptionally high implied PCEs > 28%, which could be achieved with ideal transport layers. Finally, strategies are presented to reduce both the ideality factor and transport losses to push the efficiency to the thermodynamic limit.
T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1434
KW - non-radiative interface recombination
KW - perovskite solar cells
KW - photoluminescence
Y1 - 2020
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-516622
SN - 1866-8372
IS - 17
ER -
TY - JOUR
A1 - Mattern, Maximilian
A1 - Pudell, Jan-Etienne
A1 - Dumesnil, Karine
A1 - Reppert, Alexander von
A1 - Bargheer, Matias
T1 - Towards shaping picosecond strain pulses via magnetostrictive transducers
JF - Photoacoustics
N2 - Using time-resolved x-ray diffraction, we demonstrate the manipulation of the picosecond strain response of a metallic heterostructure consisting of a dysprosium (Dy) transducer and a niobium (Nb) detection layer by an external magnetic field. We utilize the first-order ferromagnetic–antiferromagnetic phase transition of the Dy layer, which provides an additional large contractive stress upon laser excitation compared to its zerofield response. This enhances the laser-induced contraction of the transducer and changes the shape of the picosecond strain pulses driven in Dy and detected within the buried Nb layer. Based on our experiment with rare-earth metals we discuss required properties for functional transducers, which may allow for novel field-control of the emitted picosecond strain pulses.
KW - picosecond ultrasonics
KW - magnetostriction
KW - ultrafast x-ray diffraction
KW - ultrafast photoacoustics
KW - nanoscale heat transfer
KW - negative thermal expansion
Y1 - 2023
U6 - https://doi.org/10.1016/j.pacs.2023.100463
SN - 2213-5979
VL - 30
PB - Elsevier
CY - Amsterdam
ER -
TY - JOUR
A1 - Brinkmann, Kai Oliver
A1 - Becker, Tim
A1 - Zimmermann, Florian
A1 - Kreusel, Cedric
A1 - Gahlmann, Tobias
A1 - Theisen, Manuel
A1 - Haeger, Tobias
A1 - Olthof, Selina
A1 - Tückmantel, Christian
A1 - Günster, M.
A1 - Maschwitz, Timo
A1 - Göbelsmann, Fabian
A1 - Koch, Christine
A1 - Hertel, Dirk
A1 - Caprioglio, Pietro
A1 - Peña-Camargo, Francisco
A1 - Perdigón-Toro, Lorena
A1 - Al-Ashouri, Amran
A1 - Merten, Lena
A1 - Hinderhofer, Alexander
A1 - Gomell, Leonie
A1 - Zhang, Siyuan
A1 - Schreiber, Frank
A1 - Albrecht, Steve
A1 - Meerholz, Klaus
A1 - Neher, Dieter
A1 - Stolterfoht, Martin
A1 - Riedl, Thomas
T1 - Perovskite-organic tandem solar cells with indium oxide interconnect
JF - Nature
N2 - Multijunction solar cells can overcome the fundamental efficiency limits of single-junction devices. The bandgap tunability of metal halide perovskite solar cells renders them attractive for multijunction architectures(1). Combinations with silicon and copper indium gallium selenide (CIGS), as well as all-perovskite tandem cells, have been reported(2-5). Meanwhile, narrow-gap non-fullerene acceptors have unlocked skyrocketing efficiencies for organic solar cells(6,7). Organic and perovskite semiconductors are an attractive combination, sharing similar processing technologies. Currently, perovskite-organic tandems show subpar efficiencies and are limited by the low open-circuit voltage (V-oc) of wide-gap perovskite cells(8) and losses introduced by the interconnect between the subcells(9,10). Here we demonstrate perovskite-organic tandem cells with an efficiency of 24.0 per cent (certified 23.1 per cent) and a high V-oc of 2.15 volts. Optimized charge extraction layers afford perovskite subcells with an outstanding combination of high V-oc and fill factor. The organic subcells provide a high external quantum efficiency in the near-infrared and, in contrast to paradigmatic concerns about limited photostability of non-fullerene cells(11), show an outstanding operational stability if excitons are predominantly generated on the non-fullerene acceptor, which is the case in our tandems. The subcells are connected by an ultrathin (approximately 1.5 nanometres) metal-like indium oxide layer with unprecedented low optical/electrical losses. This work sets a milestone for perovskite-organic tandems, which outperform the best p-i-n perovskite single junctions(12) and are on a par with perovskite-CIGS and all-perovskite multijunctions(13).
Y1 - 2022
U6 - https://doi.org/10.1038/s41586-022-04455-0
SN - 0028-0836
SN - 1476-4687
VL - 604
IS - 7905
SP - 280
EP - 286
PB - Nature Research
CY - Berlin
ER -
TY - JOUR
A1 - Reppert, Alexander von
A1 - Willig, Lisa
A1 - Pudell, Jan-Etienne
A1 - Roessle, M.
A1 - Leitenberger, Wolfram
A1 - Herzog, Marc
A1 - Ganss, F.
A1 - Hellwig, O.
A1 - Bargheer, Matias
T1 - Ultrafast laser generated strain in granular and continuous FePt thin films
JF - Applied physics letters
N2 - We employ ultrafast X-ray diffraction to compare the lattice dynamics of laser-excited continuous and granular FePt films on MgO (100) substrates. Contrary to recent results on free-standing granular films, we observe in both cases a pronounced and long-lasting out-of-plane expansion. We attribute this discrepancy to the in-plane expansion, which is suppressed by symmetry in continuous films. Granular films on substrates are less constrained and already show a reduced out-of-plane contraction. Via the Poisson effect, out-of-plane contractions drive in-plane expansion and vice versa. Consistently, the granular film exhibits a short-lived out-of-plane contraction driven by ultrafast demagnetization which is followed by a reduced and delayed expansion. From the acoustic reflections of the observed strain waves at the film-substrate interface, we extract a 13% reduction of the elastic constants in thin 10 nm FePt films compared to bulk-like samples. (C) 2018 Author(s).
Y1 - 2018
U6 - https://doi.org/10.1063/1.5050234
SN - 0003-6951
SN - 1077-3118
VL - 113
IS - 12
PB - American Institute of Physics
CY - Melville
ER -
TY - JOUR
A1 - Reppert, Alexander von
A1 - Pudell, Jan-Etienne
A1 - Koc, A.
A1 - Reinhardt, M.
A1 - Leitenberger, Wolfram
A1 - Dumesnil, K.
A1 - Zamponi, Flavio
A1 - Bargheer, Matias
T1 - Persistent nonequilibrium dynamics of the thermal energies in the spin and phonon systems of an antiferromagnet
JF - Structural dynamics
N2 - We present a temperature and fluence dependent Ultrafast X-Ray Diffraction study of a laser-heated antiferromagnetic dysprosium thin film. The loss of antiferromagnetic order is evidenced by a pronounced lattice contraction. We devise a method to determine the energy flow between the phonon and spin system from calibrated Bragg peak positions in thermal equilibrium. Reestablishing the magnetic order is much slower than the cooling of the lattice, especially around the Neel temperature. Despite the pronounced magnetostriction, the transfer of energy from the spin system to the phonons in Dy is slow after the spin-order is lost. (C) 2016 Author(s).
Y1 - 2016
U6 - https://doi.org/10.1063/1.4961253
SN - 2329-7778
VL - 3
PB - American Institute of Physics
CY - Melville
ER -
TY - JOUR
A1 - Aguilera-Dena, David R.
A1 - Langer, Norbert
A1 - Antoniadis, John
A1 - Pauli, Daniel
A1 - Dessart, Luc
A1 - Vigna-Gómez, Alejandro
A1 - Gräfener, Götz
A1 - Yoon, Sung-Chul
T1 - Stripped-envelope stars in different metallicity environments: I. Evolutionary phases, classification, and populations
JF - Astronomy and astrophysics
N2 - Massive stars that become stripped of their hydrogen envelope through binary interaction or winds can be observed either as Wolf-Rayet stars, if they have optically thick winds, or as transparent-wind stripped-envelope stars. We approximate their evolution through evolutionary models of single helium stars, and compute detailed model grids in the initial mass range 1.5-70 M. for metallicities between 0.01 and 0.04, from core helium ignition until core collapse. Throughout their lifetimes some stellar models expose the ash of helium burning. We propose that models that have nitrogen-rich envelopes are candidate WN stars, while models with a carbon-rich surface are candidate WC stars during core helium burning, and WO stars afterwards. We measure the metallicity dependence of the total lifetimes of our models and the duration of their evolutionary phases. We propose an analytic estimate of the wind's optical depth to distinguish models of Wolf-Rayet stars from transparent-wind stripped-envelope stars, and find that the luminosity ranges at which WN-, WC-, and WO-type stars can exist is a strong function of metallicity. We find that all carbon-rich models produced in our grids have optically thick winds and match the luminosity distribution of observed populations. We construct population models and predict the numbers of transparent-wind stripped-envelope stars and Wolf-Rayet stars, and derive their number ratios at different metallicities. We find that as metallicity increases, the number of transparent-wind stripped-envelope stars decreases and the number of Wolf-Rayet stars increases. At high metallicities WC- and WO-type stars become more common. We apply our population models to nearby galaxies, and find that populations are more sensitive to the transition luminosity between Wolf-Rayet stars and transparent-wind helium stars than to the metallicity-dependent mass loss rates.
KW - stars: massive
KW - stars: Wolf-Rayet
KW - stars: winds, outflows
KW - binaries: general
KW - supernovae: general
Y1 - 2022
U6 - https://doi.org/10.1051/0004-6361/202142895
SN - 0004-6361
SN - 1432-0746
VL - 661
PB - EDP Sciences
CY - Les Ulis
ER -
TY - GEN
A1 - Ye, Fangyuan
A1 - Zhang, Shuo
A1 - Warby, Jonathan
A1 - Wu, Jiawei
A1 - Gutierrez-Partida, Emilio
A1 - Lang, Felix
A1 - Shah, Sahil
A1 - Saglamkaya, Elifnaz
A1 - Sun, Bowen
A1 - Zu, Fengshuo
A1 - Shoaee, Safa
A1 - Wang, Haifeng
A1 - Stiller, Burkhard
A1 - Neher, Dieter
A1 - Zhu, Wei-Hong
A1 - Stolterfoht, Martin
A1 - Wu, Yongzhen
T1 - Overcoming C₆₀-induced interfacial recombination in inverted perovskite solar cells by electron-transporting carborane
T2 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2 - Inverted perovskite solar cells still suffer from significant non-radiative recombination losses at the perovskite surface and across the perovskite/C₆₀ interface, limiting the future development of perovskite-based single- and multi-junction photovoltaics. Therefore, more effective inter- or transport layers are urgently required. To tackle these recombination losses, we introduce ortho-carborane as an interlayer material that has a spherical molecular structure and a three-dimensional aromaticity. Based on a variety of experimental techniques, we show that ortho-carborane decorated with phenylamino groups effectively passivates the perovskite surface and essentially eliminates the non-radiative recombination loss across the perovskite/C₆₀ interface with high thermal stability. We further demonstrate the potential of carborane as an electron transport material, facilitating electron extraction while blocking holes from the interface. The resulting inverted perovskite solar cells deliver a power conversion efficiency of over 23% with a low non-radiative voltage loss of 110 mV, and retain >97% of the initial efficiency after 400 h of maximum power point tracking. Overall, the designed carborane based interlayer simultaneously enables passivation, electron-transport and hole-blocking and paves the way toward more efficient and stable perovskite solar cells.
T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1317
Y1 - 2022
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-587705
SN - 1866-8372
IS - 1317
ER -
TY - JOUR
A1 - Pena-Camargo, Francisco
A1 - Thiesbrummel, Jarla
A1 - Hempel, Hannes
A1 - Musiienko, Artem
A1 - Le Corre, Vincent M.
A1 - Diekmann, Jonas
A1 - Warby, Jonathan
A1 - Unold, Thomas
A1 - Lang, Felix
A1 - Neher, Dieter
A1 - Stolterfoht, Martin
T1 - Revealing the doping density in perovskite solar cells and its impact on device performance
JF - Applied physics reviews
N2 - Traditional inorganic semiconductors can be electronically doped with high precision. Conversely, there is still conjecture regarding the assessment of the electronic doping density in metal-halide perovskites, not to mention of a control thereof. This paper presents a multifaceted approach to determine the electronic doping density for a range of different lead-halide perovskite systems. Optical and electrical characterization techniques, comprising intensity-dependent and transient photoluminescence, AC Hall effect, transfer-length-methods, and charge extraction measurements were instrumental in quantifying an upper limit for the doping density. The obtained values are subsequently compared to the electrode charge per cell volume under short-circuit conditions ( CUbi/eV), which amounts to roughly 10(16) cm(-3). This figure of merit represents the critical limit below which doping-induced charges do not influence the device performance. The experimental results consistently demonstrate that the doping density is below this critical threshold 10(12) cm(-3), which means << CUbi / e V) for all common lead-based metal-halide perovskites. Nevertheless, although the density of doping-induced charges is too low to redistribute the built-in voltage in the perovskite active layer, mobile ions are present in sufficient quantities to create space-charge-regions in the active layer, reminiscent of doped pn-junctions. These results are well supported by drift-diffusion simulations, which confirm that the device performance is not affected by such low doping densities.
Y1 - 2022
U6 - https://doi.org/10.1063/5.0085286
SN - 1931-9401
VL - 9
IS - 2
PB - AIP Publishing
CY - Melville
ER -
TY - JOUR
A1 - Stolterfoht, Martin
A1 - Grischek, Max
A1 - Caprioglio, Pietro
A1 - Wolff, Christian Michael
A1 - Gutierrez-Partida, Emilio
A1 - Peña-Camargo, Francisco
A1 - Rothhardt, Daniel
A1 - Zhang, Shanshan
A1 - Raoufi, Meysam
A1 - Wolansky, Jakob
A1 - Abdi-Jalebi, Mojtaba
A1 - Stranks, Samuel D.
A1 - Albrecht, Steve
A1 - Kirchartz, Thomas
A1 - Neher, Dieter
T1 - How to quantify the efficiency potential of neat perovskite films
BT - Perovskite semiconductors with an implied efficiency exceeding 28%
JF - Advanced Materials
N2 - Perovskite photovoltaic (PV) cells have demonstrated power conversion efficiencies (PCE) that are close to those of monocrystalline silicon cells; however, in contrast to silicon PV, perovskites are not limited by Auger recombination under 1-sun illumination. Nevertheless, compared to GaAs and monocrystalline silicon PV, perovskite cells have significantly lower fill factors due to a combination of resistive and non-radiative recombination losses. This necessitates a deeper understanding of the underlying loss mechanisms and in particular the ideality factor of the cell. By measuring the intensity dependence of the external open-circuit voltage and the internal quasi-Fermi level splitting (QFLS), the transport resistance-free efficiency of the complete cell as well as the efficiency potential of any neat perovskite film with or without attached transport layers are quantified. Moreover, intensity-dependent QFLS measurements on different perovskite compositions allows for disentangling of the impact of the interfaces and the perovskite surface on the non-radiative fill factor and open-circuit voltage loss. It is found that potassium-passivated triple cation perovskite films stand out by their exceptionally high implied PCEs > 28%, which could be achieved with ideal transport layers. Finally, strategies are presented to reduce both the ideality factor and transport losses to push the efficiency to the thermodynamic limit.
KW - non-radiative interface recombination
KW - perovskite solar cells
KW - photoluminescence
Y1 - 2020
U6 - https://doi.org/10.1002/adma.202000080
SN - 0935-9648
SN - 1521-4095
VL - 32
IS - 17
SP - 1
EP - 10
PB - Wiley-VCH
CY - Weinheim
ER -
TY - JOUR
A1 - Mattern, Maximilian
A1 - Reppert, Alexander von
A1 - Zeuschner, Steffen Peer
A1 - Pudell, Jan-Etienne
A1 - Kühne, F.
A1 - Diesing, Detlef
A1 - Herzog, Marc
A1 - Bargheer, Matias
T1 - Electronic energy transport in nanoscale Au/Fe hetero-structures in the perspective of ultrafast lattice dynamics
JF - Applied physics letters
N2 - We study the ultrafast electronic transport of energy in a photoexcited nanoscale Au/Fe hetero-structure by modeling the spatiotemporal profile of energy densities that drives transient strain, which we quantify by femtosecond x-ray diffraction. This flow of energy is relevant for intrinsic demagnetization and ultrafast spin transport. We measured lattice strain for different Fe layer thicknesses ranging from few atomic layers to several nanometers and modeled the spatiotemporal flow of energy densities. The combination of a high electron-phonon coupling coefficient and a large Sommerfeld constant in Fe is found to yield electronic transfer of nearly all energy from Au to Fe within the first hundreds of femtoseconds.
Y1 - 2022
U6 - https://doi.org/10.1063/5.0080378
SN - 0003-6951
SN - 1077-3118
VL - 120
IS - 9
PB - AIP Publishing
CY - Melville
ER -
TY - JOUR
A1 - Oran, Rona
A1 - Weiss, Benjamin P.
A1 - Santacruz-Pich, Maria De Soria
A1 - Jun, Insoo
A1 - Lawrence, David J.
A1 - Polanskey, Carol A.
A1 - Ratliff, J. Martin
A1 - Raymond, Carol A.
A1 - Ream, Jodie B.
A1 - Russell, Christopher T.
A1 - Shprits, Yuri Y.
A1 - Zuber, Maria T.
A1 - Elkins-Tanton, Linda T.
T1 - Maximum energies of trapped particles around magnetized planets and small bodies
JF - Geophysical research letters
N2 - Energetic charged particles trapped in planetary radiation belts are hazardous to spacecraft. Planned missions to iron-rich asteroids with possible strong remanent magnetic fields require an assessment of trapped particles energies. Using laboratory measurements of iron meteorites, we estimate the largest possible asteroid magnetic moment. Although weak compared to moments of planetary dynamos, the small body size may yield strong surface fields. We use hybrid simulations to confirm the formation of a magnetosphere with an extended quasi-dipolar region. However, the short length scale of the field implies that energetic particle motion would be nonadiabatic, making existing radiation belt theories not applicable. Our idealized particle simulations demonstrate that chaotic motions lead to particle loss at lower energies than those predicted by adiabatic theory, which may explain the energies of transiently trapped particles observed at Mercury, Ganymede, and Earth. However, even the most magnetized asteroids are unlikely to stably trap hazardous particles.
KW - asteroid magnetospheres
KW - (16) Psyche
KW - Psyche mission
KW - energetic
KW - particles
KW - chaotic motion
KW - hybrid simulations
Y1 - 2022
U6 - https://doi.org/10.1029/2021GL097014
SN - 0094-8276
SN - 1944-8007
VL - 49
IS - 13
PB - American Geophysical Union
CY - Washington
ER -
TY - JOUR
A1 - Koc, Azize
A1 - Reinhardt, M.
A1 - Reppert, Alexander von
A1 - Roessle, Matthias
A1 - Leitenberger, Wolfram
A1 - Dumesnil, K.
A1 - Gaal, Peter
A1 - Zamponi, Flavio
A1 - Bargheer, Matias
T1 - Ultrafast x-ray diffraction thermometry measures the influence of spin excitations on the heat transport through nanolayers
JF - Physical review : B, Condensed matter and materials physics
N2 - We investigate the heat transport through a rare earth multilayer system composed of yttrium (Y), dysprosium (Dy), and niobium (Nb) by ultrafast x-ray diffraction. This is an example of a complex heat flow problem on the nanoscale, where several different quasiparticles carry the heat and conserve a nonequilibrium for more than 10 ns. The Bragg peak positions of each layer represent layer-specific thermometers that measure the energy flow through the sample after excitation of the Y top layer with fs-laser pulses. In an experiment-based analytic solution to the nonequilibrium heat transport problem, we derive the individual contributions of the spins and the coupled electron-lattice system to the heat conduction. The full characterization of the spatiotemporal energy flow at different starting temperatures reveals that the spin excitations of antiferromagnetic Dy speed up the heat transport into the Dy layer at low temperatures, whereas the heat transport through this layer and further into the Y and Nb layers underneath is slowed down. The experimental findings are compared to the solution of the heat equation using macroscopic temperature-dependent material parameters without separation of spin and phonon contributions to the heat. We explain why the simulated energy density matches our experiment-based derivation of the heat transport, although the simulated thermoelastic strain in this simulation is not even in qualitative agreement.
Y1 - 2017
U6 - https://doi.org/10.1103/PhysRevB.96.014306
SN - 2469-9950
SN - 2469-9969
VL - 96
PB - American Physical Society
CY - College Park
ER -
TY - JOUR
A1 - Reppert, Alexander von
A1 - Puddell, J.
A1 - Koc, A.
A1 - Reinhardt, M.
A1 - Leitenberger, Wolfram
A1 - Dumesnil, K.
A1 - Zamponi, Flavio
A1 - Bargheer, Matias
T1 - Persistent nonequilibrium dynamics of the thermal energies in the spin and phonon systems of an antiferromagnet
JF - Structural dynamics
N2 - We present a temperature and fluence dependent Ultrafast X-Ray Diffraction study of a laser-heated antiferromagnetic dysprosium thin film. The loss of antiferromagnetic order is evidenced by a pronounced lattice contraction. We devise a method to determine the energy flow between the phonon and spin system from calibrated Bragg peak positions in thermal equilibrium. Reestablishing the magnetic order is much slower than the cooling of the lattice, especially around the Néel temperature. Despite the pronounced magnetostriction, the transfer of energy from the spin system to the phonons in Dy is slow after the spin-order is lost.
Y1 - 2016
U6 - https://doi.org/10.1063/1.4961253
SN - 2329-7778
VL - 3
PB - AIP Publishing LLC
CY - Melville, NY
ER -
TY - JOUR
A1 - Le Corre, Vincent M.
A1 - Diekmann, Jonas
A1 - Peña-Camargo, Francisco
A1 - Thiesbrummel, Jarla
A1 - Tokmoldin, Nurlan
A1 - Gutierrez-Partida, Emilio
A1 - Peters, Karol Pawel
A1 - Perdigón-Toro, Lorena
A1 - Futscher, Moritz H.
A1 - Lang, Felix
A1 - Warby, Jonathan
A1 - Snaith, Henry J.
A1 - Neher, Dieter
A1 - Stolterfoht, Martin
T1 - Quantification of efficiency losses due to mobile ions in Perovskite solar cells via fast hysteresis measurements
JF - Solar RRL
N2 - Perovskite semiconductors differ from most inorganic and organic semiconductors due to the presence of mobile ions in the material. Although the phenomenon is intensively investigated, important questions such as the exact impact of the mobile ions on the steady-state power conversion efficiency (PCE) and stability remain. Herein, a simple method is proposed to estimate the efficiency loss due to mobile ions via "fast-hysteresis" measurements by preventing the perturbation of mobile ions out of their equilibrium position at fast scan speeds (approximate to 1000 V s(-1)). The "ion-free" PCE is between 1% and 3% higher than the steady-state PCE, demonstrating the importance of ion-induced losses, even in cells with low levels of hysteresis at typical scan speeds (approximate to 100mv s(-1)). The hysteresis over many orders of magnitude in scan speed provides important information on the effective ion diffusion constant from the peak hysteresis position. The fast-hysteresis measurements are corroborated by transient charge extraction and capacitance measurements and numerical simulations, which confirm the experimental findings and provide important insights into the charge carrier dynamics. The proposed method to quantify PCE losses due to field screening induced by mobile ions clarifies several important experimental observations and opens up a large range of future experiments.
KW - hysteresis
KW - mobile ions
KW - perovskite solar cells
Y1 - 2021
U6 - https://doi.org/10.1002/solr.202100772
SN - 2367-198X
VL - 6
IS - 4
PB - Wiley-VCH
CY - Weinheim
ER -
TY - JOUR
A1 - Zeiske, Stefan
A1 - Sandberg, Oskar J.
A1 - Zarrabi, Nasim
A1 - Wolff, Christian Michael
A1 - Raoufi, Meysam
A1 - Peña-Camargo, Francisco
A1 - Gutierrez-Partida, Emilio
A1 - Meredith, Paul
A1 - Stolterfoht, Martin
A1 - Armin, Ardalan
T1 - Static disorder in lead halide perovskites
JF - The journal of physical chemistry letters
N2 - In crystalline and amorphous semiconductors, the temperature-dependent Urbach energy can be determined from the inverse slope of the logarithm of the absorption spectrum and reflects the static and dynamic energetic disorder. Using recent advances in the sensitivity of photocurrent spectroscopy methods, we elucidate the temperature-dependent Urbach energy in lead halide perovskites containing different numbers of cation components. We find Urbach energies at room temperature to be 13.0 +/- 1.0, 13.2 +/- 1.0, and 13.5 +/- 1.0 meV for single, double, and triple cation perovskite. Static, temperature-independent contributions to the Urbach energy are found to be as low as 5.1 ?+/- 0.5, 4.7 +/- 0.3, and 3.3 +/- 0.9 meV for the same systems. Our results suggest that, at a low temperature, the dominant static disorder in perovskites is derived from zero-point phonon energy rather than structural disorder. This is unusual for solution-processed semiconductors but broadens the potential application of perovskites further to quantum electronics and devices.
KW - Cations
KW - External quantum efficiency
KW - Perovskites
KW - Solar cells
KW - Solar energy
Y1 - 2022
U6 - https://doi.org/10.1021/acs.jpclett.2c01652
SN - 1948-7185
VL - 13
IS - 31
SP - 7280
EP - 7285
PB - American Chemical Society
CY - Washington
ER -
TY - JOUR
A1 - Cervantes Villa, Juan Sebastian
A1 - Shprits, Yuri Y.
A1 - Aseev, Nikita
A1 - Drozdov, Alexander
A1 - Castillo Tibocha, Angelica Maria
A1 - Stolle, Claudia
T1 - Identifying radiation belt electron source and loss processes by assimilating spacecraft data in a three-dimensional diffusion model
JF - Journal of geophysical research : Space physics
N2 - Data assimilation aims to blend incomplete and inaccurate data with physics-based dynamical models. In the Earth's radiation belts, it is used to reconstruct electron phase space density, and it has become an increasingly important tool in validating our current understanding of radiation belt dynamics, identifying new physical processes, and predicting the near-Earth hazardous radiation environment. In this study, we perform reanalysis of the sparse measurements from four spacecraft using the three-dimensional Versatile Electron Radiation Belt diffusion model and a split-operator Kalman filter over a 6-month period from 1 October 2012 to 1 April 2013. In comparison to previous works, our 3-D model accounts for more physical processes, namely, mixed pitch angle-energy diffusion, scattering by Electromagnetic Ion Cyclotron waves, and magnetopause shadowing. We describe how data assimilation, by means of the innovation vector, can be used to account for missing physics in the model. We use this method to identify the radial distances from the Earth and the geomagnetic conditions where our model is inconsistent with the measured phase space density for different values of the invariants mu and K. As a result, the Kalman filter adjusts the predictions in order to match the observations, and we interpret this as evidence of where and when additional source or loss processes are active. The current work demonstrates that 3-D data assimilation provides a comprehensive picture of the radiation belt electrons and is a crucial step toward performing reanalysis using measurements from ongoing and future missions.
KW - acceleration
KW - code
KW - density
KW - emic waves
KW - energetic particle
KW - mechanisms
KW - reanalysis
KW - ultrarelativistic electrons
KW - weather
Y1 - 2019
U6 - https://doi.org/10.1029/2019JA027514
SN - 2169-9380
SN - 2169-9402
VL - 125
IS - 1
PB - American Geophysical Union
CY - Washington
ER -
TY - JOUR
A1 - Sander, Mathias
A1 - Koc, A.
A1 - Kwamen, C. T.
A1 - Michaels, H.
A1 - Reppert, Alexander von
A1 - Pudell, Jan-Etienne
A1 - Zamponi, Flavio
A1 - Bargheer, Matias
A1 - Sellmann, J.
A1 - Schwarzkopf, J.
A1 - Gaal, P.
T1 - Characterization of an ultrafast Bragg-Switch for shortening hard x-ray pulses
JF - Journal of applied physics
N2 - We present a nanostructured device that functions as photoacoustic hard x-ray switch. The device is triggered by femtosecond laser pulses and allows for temporal gating of hard x-rays on picosecond (ps) timescales. It may be used for pulse picking or even pulse shortening in 3rd generation synchrotron sources. Previous approaches mainly suffered from insufficient switching contrasts due to excitation-induced thermal distortions. We present a new approach where thermal distortions are spatially separated from the functional switching layers in the structure. Our measurements yield a switching contrast of 14, which is sufficient for efficient hard x-ray pulse shortening. The optimized structure also allows for utilizing the switch at high repetition rates of up to 208 kHz. Published by AIP Publishing.
Y1 - 2016
U6 - https://doi.org/10.1063/1.4967835
SN - 0021-8979
SN - 1089-7550
VL - 120
PB - American Institute of Physics
CY - Melville
ER -
TY - JOUR
A1 - Pudell, Jan-Etienne
A1 - Maznev, A. A.
A1 - Herzog, Marc
A1 - Kronseder, M.
A1 - Back, Christian H.
A1 - Malinowski, Gregory
A1 - Reppert, Alexander von
A1 - Bargheer, Matias
T1 - Layer specific observation of slow thermal equilibration in ultrathin metallic nanostructures by femtosecond X-ray diffraction
JF - Nature Communications
N2 - Ultrafast heat transport in nanoscale metal multilayers is of great interest in the context of optically induced demagnetization, remagnetization and switching. If the penetration depth of light exceeds the bilayer thickness, layer-specific information is unavailable from optical probes. Femtosecond diffraction experiments provide unique experimental access to heat transport over single digit nanometer distances. Here, we investigate the structural response and the energy flow in the ultrathin double-layer system: gold on ferromagnetic nickel. Even though the excitation pulse is incident from the Au side, we observe a very rapid heating of the Ni lattice, whereas the Au lattice initially remains cold. The subsequent heat transfer from Ni to the Au lattice is found to be two orders of magnitude slower than predicted by the conventional heat equation and much slower than electron-phonon coupling times in Au. We present a simplified model calculation highlighting the relevant thermophysical quantities.
Y1 - 2018
U6 - https://doi.org/10.1038/s41467-018-05693-5
SN - 2041-1723
VL - 9
PB - Nature Publ. Group
CY - London
ER -
TY - JOUR
A1 - Pudell, Jan-Etienne
A1 - Reppert, Alexander von
A1 - Schick, D.
A1 - Zamponi, F.
A1 - Rössle, Matthias
A1 - Herzog, Marc
A1 - Zabel, Hartmut
A1 - Bargheer, Matias
T1 - Ultrafast negative thermal expansion driven by spin disorder
JF - Physical review : B, Condensed matter and materials physics
N2 - We measure the transient strain profile in a nanoscale multilayer system composed of yttrium, holmium, and niobium after laser excitation using ultrafast x-ray diffraction. The strain propagation through each layer is determined by transient changes in the material-specific Bragg angles. We experimentally derive the exponentially decreasing stress profile driving the strain wave and show that it closely matches the optical penetration depth. Below the Neel temperature of Ho, the optical excitation triggers negative thermal expansion, which is induced by a quasi-instantaneous contractive stress and a second contractive stress contribution increasing on a 12-ps timescale. These two timescales were recently measured for the spin disordering in Ho [Rettig et al., Phys. Rev. Lett. 116, 257202 (2016)]. As a consequence, we observe an unconventional bipolar strain pulse with an inverted sign traveling through the heterostructure.
Y1 - 2019
U6 - https://doi.org/10.1103/PhysRevB.99.094304
SN - 2469-9950
SN - 2469-9969
VL - 99
IS - 9
PB - American Physical Society
CY - College Park
ER -
TY - JOUR
A1 - Grischek, Max
A1 - Caprioglio, Pietro
A1 - Zhang, Jiahuan
A1 - Pena-Camargo, Francisco
A1 - Sveinbjornsson, Kari
A1 - Zu, Fengshuo
A1 - Menzel, Dorothee
A1 - Warby, Jonathan
A1 - Li, Jinzhao
A1 - Koch, Norbert
A1 - Unger, Eva
A1 - Korte, Lars
A1 - Neher, Dieter
A1 - Stolterfoht, Martin
A1 - Albrecht, Steve
T1 - Efficiency Potential and Voltage Loss of Inorganic CsPbI2Br Perovskite Solar Cells
JF - Solar RRL
N2 - Inorganic perovskite solar cells show excellent thermal stability, but the reported power conversion efficiencies are still lower than for organic-inorganic perovskites. This is mainly caused by lower open-circuit voltages (V(OC)s). Herein, the reasons for the low V-OC in inorganic CsPbI2Br perovskite solar cells are investigated. Intensity-dependent photoluminescence measurements for different layer stacks reveal that n-i-p and p-i-n CsPbI2Br solar cells exhibit a strong mismatch between quasi-Fermi level splitting (QFLS) and V-OC. Specifically, the CsPbI2Br p-i-n perovskite solar cell has a QFLS-e center dot V-OC mismatch of 179 meV, compared with 11 meV for a reference cell with an organic-inorganic perovskite of similar bandgap. On the other hand, this study shows that the CsPbI2Br films with a bandgap of 1.9 eV have a very low defect density, resulting in an efficiency potential of 20.3% with a MeO-2PACz hole-transporting layer and 20.8% on compact TiO2. Using ultraviolet photoelectron spectroscopy measurements, energy level misalignment is identified as a possible reason for the QFLS-e center dot V-OC mismatch and strategies for overcoming this V-OC limitation are discussed. This work highlights the need to control the interfacial energetics in inorganic perovskite solar cells, but also gives promise for high efficiencies once this issue is resolved.
KW - CsPbI2Br
KW - efficiency potentials
KW - inorganic perovskites
KW - photoluminescence
KW - solar cells
KW - voltage losses
Y1 - 2022
U6 - https://doi.org/10.1002/solr.202200690
SN - 2367-198X
VL - 6
IS - 11
PB - Wiley-VCH
CY - Weinheim
ER -
TY - JOUR
A1 - Di Bello, Costantino
A1 - Hartmann, Alexander K.
A1 - Majumdar, Satya N.
A1 - Mori, Francesco
A1 - Rosso, Alberto
A1 - Schehr, Gregory
T1 - Current fluctuations in stochastically resetting particle systems
JF - Physical review : E, Statistical, nonlinear and soft matter physics
N2 - We consider a system of noninteracting particles on a line with initial positions distributed uniformly with density ? on the negative half-line. We consider two different models: (i) Each particle performs independent Brownian motion with stochastic resetting to its initial position with rate r and (ii) each particle performs run -and-tumble motion, and with rate r its position gets reset to its initial value and simultaneously its velocity gets randomized. We study the effects of resetting on the distribution P(Q, t) of the integrated particle current Q up to time t through the origin (from left to right). We study both the annealed and the quenched current distributions and in both cases, we find that resetting induces a stationary limiting distribution of the current at long times. However, we show that the approach to the stationary state of the current distribution in the annealed and the quenched cases are drastically different for both models. In the annealed case, the whole distribution P-an(Q, t) approaches its stationary limit uniformly for all Q. In contrast, the quenched distribution P-qu(Q, t) attains its stationary form for Q < Q(crit)(t), while it remains time dependent for Q > Q(crit)(t). We show that Q(crit)(t) increases linearly with t for large t. On the scale where Q <; Q(crit)(t), we show that P-qu(Q, t) has an unusual large deviation form with a rate function that has a third-order phase transition at the critical point. We have computed the associated rate functions analytically for both models. Using an importance sampling method that allows to probe probabilities as tiny as 10-14000, we were able to compute numerically this nonanalytic rate function for the resetting Brownian dynamics and found excellent agreement with our analytical prediction.
Y1 - 2023
U6 - https://doi.org/10.1103/PhysRevE.108.014112
SN - 2470-0045
SN - 2470-0053
VL - 108
IS - 1
PB - American Physical Society
CY - College Park
ER -
TY - THES
A1 - Fritzewski, Dario Jasper
T1 - From fast to slow rotation in the open clusters NGC 2516 and NGC 3532
T1 - Der Übergang von schneller zu langsamer Rotation in den offenen Sternhaufen NGC 2516 und NGC 3532
N2 - Angular momentum is a particularly sensitive probe into stellar evolution because it changes significantly over the main sequence life of a star. In this thesis, I focus on young main sequence stars of which some feature a rapid evolution in their rotation rates. This transition from fast to slow rotation is inadequately explored observationally and this work aims to provide insights into the properties and time scales but also investigates stellar rotation in young open clusters in general.
I focus on the two open clusters NGC 2516 and NGC 3532 which are ~150 Myr (zero-age main sequence age) and ~300 Myr old, respectively. From 42 d-long time series photometry obtained at the Cerro Tololo Inter-American Observatory, I determine stellar rotation periods in both clusters. With accompanying low resolution spectroscopy, I measure radial velocities and chromospheric emission for NGC 3532, the former to establish a clean membership and the latter to probe the rotation-activity connection.
The rotation period distribution derived for NGC 2516 is identical to that of four other coeval open clusters, including the Pleiades, which shows the universality of stellar rotation at the zero-age main sequence. Among the similarities (with the Pleiades) the "extended slow rotator sequence" is a new, universal, yet sparse, feature in the colour-period diagrams of open clusters. From a membership study, I find NGC 3532 to be one of the richest nearby open clusters with 660 confirmed radial velocity members and to be slightly sub-solar in metallicity. The stellar rotation periods for NGC 3532 are the first published for a 300 Myr-old open cluster, a key age to understand the transition from fast to slow rotation. The fast rotators at this age have significantly evolved beyond what is observed in NGC 2516 which allows to estimate the spin-down timescale and to explore the issues that angular momentum models have in describing this transition. The transitional sequence is also clearly identified in a colour-activity diagram of stars in NGC 3532. The synergies of the chromospheric activity and the rotation periods allow to understand the colour-activity-rotation connection for NGC 3532 in unprecedented detail and to estimate additional rotation periods for members of NGC 3532, including stars on the "extended slow rotator sequence".
In conclusion, this thesis probes the transition from fast to slow rotation but has also more general implications for the angular momentum evolution of young open clusters.
N2 - Entgegen anderer Parameter ändert sich der Drehimpuls von kühlen Hauptreihensternen stark und eignet sich daher gut zur Untersuchung der Sternentwicklung. In dieser Arbeit fokussiere ich mich auf junge Hauptreihensterne, von denen einige einen ausgeprägten Übergang in ihren Rotationsperioden aufweisen. Dieser Übergang von schneller zu langsamer Rotation ist empirisch nur unzureichend erforscht und diese Arbeit zielt darauf ab, Einblicke in seine Eigenschaften und Zeitskalen zu geben, sie untersucht aber auch die stellare Rotation in jungen offenen Sternhaufen im Allgemeinen.
Ich konzentriere mich auf die beiden offenen Sternhaufen NGC 2516 und NGC 3532, die ~150 Myr (Nullalter-Hauptreihe) bzw. ~300 Myr alt sind. Aus einer 42 Tage langen photometrischen Zeitreihe, die am Cerro Tololo Inter-American Observatory gewonnen wurde, bestimme ich Rotationsperioden in beiden Sternhaufen. Darüber hinaus messe ich mit niedrig auflösender Spektroskopie Radialgeschwindigkeiten und die chromosphärische Emission für Sterne in NGC 3532, erstere um eine sichere Mitgliedschaft zu etablieren und letztere um den Zusammenhang zwischen Rotation und Aktivität zu untersuchen.
Die für NGC 2516 abgeleitete Rotationsperiodenverteilung ist identisch mit der von vier anderen gleichaltrigen offenen Sternhaufen, einschließlich der Plejaden, was die Gleichheit und Grundsätzlichkeit der Sternrotation auf der Nullalter-Hauptreihe zeigt. Neben den Ähnlichkeiten (mit den Plejaden) ist die "extended slow rotator sequence" ein neues, universelles, aber seltenes Merkmal in den Farben-Perioden-Diagrammen offener Sternhaufen.
Aus einer Mitgliedschaftsstudie geht hervor, dass NGC 3532 mit 660 bestätigten Radialgeschwindigkeitsmitgliedern einer der größten nahen offenen Sternhaufen ist. Zudem weist er eine leicht sub-solare Metallizität auf.
Die Rotationsperioden für NGC 3532 sind die ersten, die für einen 300 Myr alten offenen Sternhaufen veröffentlicht wurden, ein wichtiges Alter, um den Übergang von schneller zu langsamer Rotation zu verstehen. Die schnellen Rotatoren in diesem Alter sind deutlich weiter entwickelt als in NGC 2516 beobachtet, was es erlaubt, die Zeitskala für den Drehimpulsverlust abzuschätzen und die Probleme zu untersuchen, die Drehimpulsmodelle bei der Beschreibung dieses Übergangs haben.
Die Übergangssequenz ist auch in einem Farben-Aktivitäts-Diagramm von Sternen in NGC 3532 deutlich zu erkennen. Die Synergien zwischen der chromosphärischen Aktivität und den Rotationsperioden erlauben es, den Zusammenhang zwischen intrinsischer Farbe, Aktivität und Rotation für NGC 3532 in einzigartigem Detail zu verstehen und zusätzliche Rotationsperioden für Mitglieder von NGC 3532 abzuschätzen, einschließlich der Sterne auf der "extended slow rotator sequence".
Zusammenfassend untersucht diese Arbeit den Übergang von schneller zu langsamer Rotation, hat aber auch allgemeinere Implikationen für die Drehimpulsentwicklung von jungen offenen Sternhaufen.
KW - Astronomy
KW - Astrophysics
KW - cool stars
KW - angular momentum loss
KW - stellar rotation
KW - photometry
KW - spectroscopy
KW - gyrochronology
KW - chromospheric activity
KW - stellar activity
KW - open cluster
KW - NGC 2516
KW - NGC 3532
KW - Astronomie
KW - Astrophysik
KW - NGC 2516
KW - NGC 3532
KW - Drehimpulsverlust
KW - chromospherische Aktivität
KW - kühle Sterne
KW - Gyrochronologie
KW - offener Sternhaufen
KW - Photometrie
KW - Spektroskopie
KW - stellare Aktivität
KW - stellare Rotation
Y1 - 2021
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-531356
ER -
TY - JOUR
A1 - Abdalla, H.
A1 - Adam, R.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Angüner, Ekrem Oǧuzhan
A1 - Arcaro, C.
A1 - Armand, C.
A1 - Armstrong, T.
A1 - Ashkar, H.
A1 - Backes, M.
A1 - Baghmanyan, V.
A1 - Martins, V. Barbosa
A1 - Barnacka, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Berge, D.
A1 - Bernlohr, K.
A1 - Bi, B.
A1 - Bottcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - de Lavergne, M. de Bony
A1 - Bordas, Pol
A1 - Breuhaus, M.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Buchele, M.
A1 - Bulik, T.
A1 - Bylund, T.
A1 - Caroff, S.
A1 - Carosi, A.
A1 - Casanova, Sabrina
A1 - Chand, T.
A1 - Chandra, S.
A1 - Chen, A.
A1 - Cotter, G.
A1 - Curylo, M.
A1 - Mbarubucyeye, J. Damascene
A1 - Davids, I. D.
A1 - Davies, J.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Dmytriiev, A.
A1 - Donath, A.
A1 - Doroshenko, V.
A1 - Duffy, C.
A1 - Dyks, J.
A1 - Egberts, Kathrin
A1 - Eichhorn, F.
A1 - Einecke, S.
A1 - Emery, G.
A1 - Ernenwein, J. -P.
A1 - Feijen, K.
A1 - Fegan, S.
A1 - Fiasson, A.
A1 - de Clairfontaine, G. Fichet
A1 - Fontaine, G.
A1 - Funk, S.
A1 - Fussling, Matthias
A1 - Gabici, S.
A1 - Gallant, Y. A.
A1 - Giavitto, G.
A1 - Giunti, L.
A1 - Glawion, D.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M. -H.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hermann, G.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holch, T. L.
A1 - Holler, M.
A1 - Horbe, M.
A1 - Horns, D.
A1 - Huber, D.
A1 - Jamrozy, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jardin-Blicq, A.
A1 - Joshi, V.
A1 - Jung-Richardt, I.
A1 - Kasai, E.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - Klepser, S.
A1 - Kluzniak, W.
A1 - Komin, Nu.
A1 - Konno, R.
A1 - Kosack, K.
A1 - Kostunin, D.
A1 - Kreter, M.
A1 - Lamanna, G.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Levy, C.
A1 - Lohse, T.
A1 - Lypova, I.
A1 - Mackey, J.
A1 - Majumdar, J.
A1 - Malyshev, D.
A1 - Malyshev, D.
A1 - Marandon, V.
A1 - Marchegiani, P.
A1 - Marcowith, Alexandre
A1 - Mares, A.
A1 - Marti-Devesa, G.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitchell, A.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Montanari, A.
A1 - Moore, C.
A1 - Morris, P.
A1 - Moulin, Emmanuel
A1 - Muller, J.
A1 - Murach, T.
A1 - Nakashima, K.
A1 - Nayerhoda, A.
A1 - de Naurois, M.
A1 - Ndiyavala, H.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - O'Brien, Patrick
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Olivera-Nieto, L.
A1 - Wilhelmi, E. de Ona
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Panny, S.
A1 - Parsons, R. D.
A1 - Peron, G.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poireau, V.
A1 - Noel, A. Priyana
A1 - Prokhorov, D. A.
A1 - Prokoph, H.
A1 - Puhlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Rauth, R.
A1 - Reichherzer, P.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Remy, Q.
A1 - Renaud, M.
A1 - Rieger, F.
A1 - Rinchiuso, L.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Ruiz-Velasco, E.
A1 - Sahakian, V.
A1 - Sailer, S.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Scalici, M.
A1 - Schussler, F.
A1 - Schutte, H. M.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Senniappan, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shiningayamwe, K.
A1 - Simoni, R.
A1 - Sinha, A.
A1 - Sol, H.
A1 - Specovius, A.
A1 - Spencer, S.
A1 - Spir-Jacob, M.
A1 - Stawarz, L.
A1 - Sun, L.
A1 - Steenkamp, R.
A1 - Stegmann, C.
A1 - Steinmassl, S.
A1 - Steppa, C.
A1 - Takahashi, T.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Tomankova, L.
A1 - Trichard, C.
A1 - Tsirou, M.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Volk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Watson, J.
A1 - Werner, F.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Wong, Yu Wun
A1 - Yusafzai, A.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zargaryan, D.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zhu, S. J.
A1 - Ziegler, A.
A1 - Zorn, J.
A1 - Zouari, S.
A1 - Zywucka, N.
T1 - An extreme particle accelerator in the Galactic plane
BT - HESS J1826-130
JF - Astronomy and astrophysics : an international weekly journal
N2 - The unidentified very-high-energy (VHE; E > 0.1 TeV) gamma -ray source, HESS J1826-130, was discovered with the High Energy Stereoscopic System (HESS) in the Galactic plane. The analysis of 215 h of HESS data has revealed a steady gamma -ray flux from HESS J1826-130, which appears extended with a half-width of 0.21 degrees +/- 0.02
(stat)degrees
stat degrees +/- 0.05
(sys)degrees sys degrees . The source spectrum is best fit with either a power-law function with a spectral index Gamma = 1.78 +/- 0.10(stat) +/- 0.20(sys) and an exponential cut-off at 15.2
(+5.5)(-3.2) -3.2+5.5 TeV, or a broken power-law with Gamma (1) = 1.96 +/- 0.06(stat) +/- 0.20(sys), Gamma (2) = 3.59 +/- 0.69(stat) +/- 0.20(sys) for energies below and above E-br = 11.2 +/- 2.7 TeV, respectively. The VHE flux from HESS J1826-130 is contaminated by the extended emission of the bright, nearby pulsar wind nebula, HESS J1825-137, particularly at the low end of the energy spectrum. Leptonic scenarios for the origin of HESS J1826-130 VHE emission related to PSR J1826-1256 are confronted by our spectral and morphological analysis. In a hadronic framework, taking into account the properties of dense gas regions surrounding HESS J1826-130, the source spectrum would imply an astrophysical object capable of accelerating the parent particle population up to greater than or similar to 200 TeV. Our results are also discussed in a multiwavelength context, accounting for both the presence of nearby supernova remnants, molecular clouds, and counterparts detected in radio, X-rays, and TeV energies.
KW - ISM: supernova remnants
KW - ISM: clouds
KW - gamma rays: general
KW - gamma rays:
KW - ISM
Y1 - 2020
U6 - https://doi.org/10.1051/0004-6361/202038851
SN - 0004-6361
SN - 1432-0746
VL - 644
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Andersson, T.
A1 - Anguener, E. O.
A1 - Arrieta, M.
A1 - Aubert, P.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Boettcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Carr, J.
A1 - Carrigan, S.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - Devin, J.
A1 - dewilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M. -H.
A1 - Hadasch, D.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Settimo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - Valerius, K.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywucka, N.
T1 - The population of TeV pulsar wind nebulae in the HESS Galactic Plane Survey
JF - Astronomy and astrophysics : an international weekly journal
N2 - The nine-year H.E.S.S. Galactic Plane Survey (HGPS) has yielded the most uniform observation scan of the inner Milky Way in the TeV gamma-ray band to date. The sky maps and source catalogue of the HGPS allow for a systematic study of the population of TeV pulsar wind nebulae found throughout the last decade. To investigate the nature and evolution of pulsar wind nebulae, for the first time we also present several upper limits for regions around pulsars without a detected TeV wind nebula. Our data exhibit a correlation of TeV surface brightness with pulsar spindown power (E) over dot. This seems to be caused both by an increase of extension with decreasing (E) over dot, and hence with time, compatible with a power law R-PWN((E) over dot) similar to(E) over dot(0.65 +/- 0.20), and by a mild decrease of TeV gamma-ray luminosity with decreasing (E) over dot, compatible with L-1 (10 TeV) similar to (E) over dot(0.59 +/- 0.21). We also find that the off sets of pulsars with respect to the wind nebula centre with ages around 10 kyr are frequently larger than can be plausibly explained by pulsar proper motion and could be due to an asymmetric environment. In the present data, it seems that a large pulsar off set is correlated with a high apparent TeV efficiency L1- 10 TeV / (E) over dot. In addition to 14 HGPS sources considered firmly identified pulsar wind nebulae and 5 additional pulsar wind nebulae taken from literature, we find 10 HGPS sources that are likely TeV pulsar wind nebula candidates. Using a model that subsumes the present common understanding of the very high-energy radiative evolution of pulsar wind nebulae, we find that the trends and variations of the TeV observables and limits can be reproduced to a good level, drawing a consistent picture of present-day TeV data and theory.
KW - gamma rays: general
KW - catalogs
KW - surveys
KW - ISM: supernova remnants
KW - pulsars: general
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201629377
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Angüner, Ekrem Oǧuzhan
A1 - Arakawa, M.
A1 - Arcaro, C.
A1 - Armand, C.
A1 - Arrieta, M.
A1 - Backes, M.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Bottcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bonnefoy, S.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Buechele, M.
A1 - Bulik, T.
A1 - Bylund, T.
A1 - Capasso, M.
A1 - Caroff, S.
A1 - Carosi, A.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chand, T.
A1 - Chandra, S.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Colafrancesco, S.
A1 - Condon, B.
A1 - Davids, I. D.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Dmytriiev, A.
A1 - Donath, A.
A1 - Doroshenko, V
A1 - Dyks, J.
A1 - Egberts, Kathrin
A1 - Emery, G.
A1 - Ernenwein, J-P
A1 - Eschbach, S.
A1 - Fegan, S.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gallant, Y. A.
A1 - Gate, F.
A1 - Giavitto, G.
A1 - Glawion, D.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M-H
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holch, Tim Lukas
A1 - Holler, M.
A1 - Horns, D.
A1 - Huber, D.
A1 - Iwasaki, H.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jouvin, L.
A1 - Jung-Richardt, I
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - King, J.
A1 - Klepser, S.
A1 - Kluzniak, W.
A1 - Komin, Nu
A1 - Kosack, K.
A1 - Kraus, M.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lefaucheur, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J-P
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lopez-Coto, R.
A1 - Lypova, I
A1 - Malyshev, D.
A1 - Marandon, V
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marti-Devesa, G.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Meintjes, P. J.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Moore, C.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Ndiyavala, H.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Perennes, C.
A1 - Petrucci, P-O
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poireau, V
A1 - Noel, A. Priyana
A1 - Prokhorov, D. A.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Rauth, R.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - Rieger, F.
A1 - Rinchiuso, L.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Ruiz-Velasco, E.
A1 - Sahakian, V
A1 - Saito, S.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schutte, H.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Senniappan, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I
A1 - Shiningayamwe, K.
A1 - Simoni, R.
A1 - Sinha, A.
A1 - Sol, H.
A1 - Specovius, A.
A1 - Spir-Jacob, M.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Steppa, Constantin Beverly
A1 - Takahashi, T.
A1 - Tavernet, J-P
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsirou, M.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Yang, R.
A1 - Yoneda, H.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zorn, J.
A1 - Zywucka, N.
T1 - Particle transport within the pulsar wind nebula HESS J1825-137
JF - Astronomy and astrophysics : an international weekly journal
N2 - Context. We present a detailed view of the pulsar wind nebula (PWN) HESS J1825-137. We aim to constrain the mechanisms dominating the particle transport within the nebula, accounting for its anomalously large size and spectral characteristics. Aims. The nebula was studied using a deep exposure from over 12 years of H.E.S.S. I operation, together with data from H.E.S.S. II that improve the low-energy sensitivity. Enhanced energy-dependent morphological and spatially resolved spectral analyses probe the very high energy (VHE, E > 0.1 TeV) gamma-ray properties of the nebula. Methods. The nebula emission is revealed to extend out to 1.5 degrees from the pulsar, similar to 1.5 times farther than previously seen, making HESS J1825-137, with an intrinsic diameter of similar to 100 pc, potentially the largest gamma-ray PWN currently known. Characterising the strongly energy-dependent morphology of the nebula enables us to constrain the particle transport mechanisms. A dependence of the nebula extent with energy of R proportional to E alpha with alpha = -0.29 +/- 0.04(stat) +/- 0.05(sys) disfavours a pure diffusion scenario for particle transport within the nebula. The total gamma-ray flux of the nebula above 1 TeV is found to be (1.12 +/- 0.03(stat) +/- 0.25(sys)) +/- 10(-11) cm(-2) s(-1), corresponding to similar to 64% of the flux of the Crab nebula. Results. HESS J1825-137 is a PWN with clearly energy-dependent morphology at VHE gamma-ray energies. This source is used as a laboratory to investigate particle transport within intermediate-age PWNe. Based on deep observations of this highly spatially extended PWN, we produce a spectral map of the region that provides insights into the spectral variation within the nebula.
KW - gamma rays: general
KW - acceleration of particles
KW - convection
KW - diffusion
KW - pulsars: general
Y1 - 2019
U6 - https://doi.org/10.1051/0004-6361/201834335
SN - 1432-0746
VL - 621
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Anguener, E. O.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Birsin, E.
A1 - Blackwell, R.
A1 - Boettcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Bulik, T.
A1 - Carr, J.
A1 - Casanova, Sabrina
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Hadasch, D.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lorentz, M.
A1 - Lu, C. -C.
A1 - Lui, R.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reichardt, I.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seyffert, A. S.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tuffs, R.
A1 - Valerius, K.
A1 - van der Walt, J.
A1 - van Eldik, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - Weidinger, M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Zywucka, N.
T1 - Detailed spectral and morphological analysis of the shell type supernova remnant RCW 86
JF - Astronomy and astrophysics : an international weekly journal
N2 - Aims. We aim for an understanding of the morphological and spectral properties of the supernova remnant RCW 86 and for insights into the production mechanism leading to the RCW 86 very high-energy gamma-ray emission. Methods. We analyzed High Energy Spectroscopic System (H.E.S.S.) data that had increased sensitivity compared to the observations presented in the RCW 86 H.E.S.S. discovery publication. Studies of the morphological correlation between the 0.5-1 keV X-ray band, the 2-5 keV X-ray band, radio, and gamma-ray emissions have been performed as well as broadband modeling of the spectral energy distribution with two different emission models. Results. We present the first conclusive evidence that the TeV gamma-ray emission region is shell-like based on our morphological studies. The comparison with 2-5 keV X-ray data reveals a correlation with the 0.4-50 TeV gamma-ray emission. The spectrum of RCW 86 is best described by a power law with an exponential cutoff at E-cut = (3.5 +/- 1.2(stat)) TeV and a spectral index of Gamma approximate to 1.6 +/- 0.2. A static leptonic one-zone model adequately describes the measured spectral energy distribution of RCW 86, with the resultant total kinetic energy of the electrons above 1 GeV being equivalent to similar to 0.1% of the initial kinetic energy of a Type Ia supernova explosion (10(51) erg). When using a hadronic model, a magnetic field of B approximate to 100 mu G is needed to represent the measured data. Although this is comparable to formerly published estimates, a standard E-2 spectrum for the proton distribution cannot describe the gamma-ray data. Instead, a spectral index of Gamma(p) approximate to 1.7 would be required, which implies that similar to 7 x 10(49)/n(cm-3) erg has been transferred into high-energy protons with the effective density n(cm-3) = n/1 cm(-3). This is about 10% of the kinetic energy of a typical Type Ia supernova under the assumption of a density of 1 cm(-3).
KW - astroparticle physics
KW - gamma rays: general
KW - ISM: supernova remnants
KW - cosmic rays
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201526545
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, H.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Andersson, T.
A1 - Anguener, E. O.
A1 - Arrieta, M.
A1 - Aubert, P.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernlorhr, K.
A1 - Blackwell, R.
A1 - Bottcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Carr, J.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Decock, J.
A1 - Degrange, B.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M. -H.
A1 - Hadasch, D.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khelifi, B.
A1 - Er, M. Kie Ff
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Krayzel, F.
A1 - Kruger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, E.
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Settimo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Ert, Ff
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian Michael
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywucka, N.
T1 - Characterizing the gamma-ray long-term variability of PKS2155 304 with HESS and Fermi-LAT
JF - Astronomy and astrophysics : an international weekly journal
N2 - Studying the temporal variability of BL Lac objects at the highest energies provides unique insights into the extreme physical processes occurring in relativistic jets and in the vicinity of super-massive black holes. To this end, the long-term variability of the BL Lac object PKS 2155 304 is analyzed in the high (HE, 100MeV < E < 300 GeV) and very high energy (VHE, E > 200 GeV) gamma-ray domain. Over the course of similar to 9 yr of H. E. S. S. observations the VHE light curve in the quiescent state is consistent with a log-normal behavior. The VHE variability in this state is well described by flicker noise (power-spectral-density index beta(VHE) = 1 .10(+ 0 : 10) (0 : 13)) on timescales larger than one day. An analysis of similar to 5.5 yr of HE Fermi-LAT data gives consistent results (beta(HE) = 1 : 20(+ 0 : 21) (0 : 23), on timescales larger than 10 days) compatible with the VHE findings. The HE and VHE power spectral densities show a scale invariance across the probed time ranges. A direct linear correlation between the VHE and HE fluxes could neither be excluded nor firmly established. These long-term-variability properties are discussed and compared to the red noise behavior (beta similar to 2) seen on shorter timescales during VHE-flaring states. The difference in power spectral noise behavior at VHE energies during quiescent and flaring states provides evidence that these states are influenced by different physical processes, while the compatibility of the HE and VHE long-term results is suggestive of a common physical link as it might be introduced by an underlying jet-disk connection.
KW - galaxies: active
KW - BL Lacertae objects: individual: PKS 2155-304
KW - gamma rays: galaxies
KW - galaxies: jets
KW - galaxies: nuclei
KW - radiation mechanisms: non-thermal
Y1 - 2017
U6 - https://doi.org/10.1051/0004-6361/201629419
SN - 1432-0746
SN - 0004-6361
VL - 598
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Anton, Gisela
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Bissaldi, E.
A1 - Biteau, Jonathan
A1 - Boettcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Brucker, J.
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chadwick, Paula M.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Cheesebrough, A.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Dalton, M.
A1 - Daniel, M. K.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Dickinson, H. J.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, Matthias
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Harris, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, M.
A1 - Horns, D.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kneiske, T.
A1 - Kolitzus, D.
A1 - Komin, Nu
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lennarz, D.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - McComb, T. J. L.
A1 - Mehault, J.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Naumann, C. L.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Oakes, L.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perez, J.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Raue, M.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Rob, L.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sol, H.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Szostek, A.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorster, M.
A1 - Vuillaume, T.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Ward, M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Zabalza, V.
A1 - Zacharias, M.
A1 - Zajczyk, A.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. -S.
T1 - TeV gamma-ray observations of the young synchrotron-dominated SNRs G1.9+0.3 and G330.2+1.0 with HESS
JF - Monthly notices of the Royal Astronomical Society
N2 - The non-thermal nature of the X-ray emission from the shell-type supernova remnants (SNRs) G1.9+0.3 and G330.2+1.0 is an indication of intense particle acceleration in the shock fronts of both objects. This suggests that the SNRs are prime candidates for very-high-energy (VHE; E > 0.1 TeV) gamma-ray observations. G1.9+0.3, recently established as the youngest known SNR in the Galaxy, also offers a unique opportunity to study the earliest stages of SNR evolution in the VHE domain. The purpose of this work is to probe the level of VHE gamma-ray emission from both SNRs and use this to constrain their physical properties. Observations were conducted with the H. E. S. S. (High Energy Stereoscopic System) Cherenkov Telescope Array over a more than six-year period spanning 2004-2010. The obtained data have effective livetimes of 67 h for G1.9+0.3 and 16 h for G330.2+1.0. The data are analysed in the context of the multiwavelength observations currently available and in the framework of both leptonic and hadronic particle acceleration scenarios. No significant gamma-ray signal from G1.9+0.3 or G330.2+1.0 was detected. Upper limits (99 per cent confidence level) to the TeV flux from G1.9+0.3 and G330.2+1.0 for the assumed spectral index Gamma = 2.5 were set at 5.6 x 10(-1)3 cm(-2) s(-1) above 0.26 TeV and 3.2 x 10(-12) cm(-2) s(-1) above 0.38 TeV, respectively. In a one-zone leptonic scenario, these upper limits imply lower limits on the interior magnetic field to B-G1.9 greater than or similar to 12 mu G for G1.9+0.3 and to B-G330 greater than or similar to 8 mu G for G330.2+1.0. In a hadronic scenario, the low ambient densities and the large distances to the SNRs result in very low predicted fluxes, for which the H.E.S.S. upper limits are not constraining.
KW - radiation mechanisms: non-thermal
KW - ISM: individual objects: SNR G1.9+0.3
KW - ISM: individual objects: SNR G330.2+1.0
KW - ISM: magnetic fields
KW - ISM: supernova remnants
KW - gamma-rays: ISM
Y1 - 2014
U6 - https://doi.org/10.1093/mnras/stu459
SN - 0035-8711
SN - 1365-2966
VL - 441
IS - 1
SP - 790
EP - 799
PB - Oxford Univ. Press
CY - Oxford
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Backes, Michael
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Berge, David
A1 - Bernhard, Sabrina
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Biteau, Jonathan
A1 - Boettcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, Johan
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bryan, Mark
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Chadwick, Paula M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - dewilt, P.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Hadasch, D.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Harris, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, Marek
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, Krzysztof
A1 - Katz, Uli
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - McComb, T. J. L.
A1 - Mehault, J.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Puehlhofer, G.
A1 - Punch, Michael
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reichardt, I.
A1 - Reimer, A.
A1 - Reimer, Olaf
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schuessler, Fabian
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, Christopher
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorster, M.
A1 - Vuillaume, T.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - Ward, M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. -S.
A1 - Fukui, Y.
T1 - Diffuse Galactic gamma-ray emission with HESS
JF - Physical review : D, Particles, fields, gravitation, and cosmology
N2 - Diffuse gamma-ray emission is the most prominent observable signature of celestial cosmic-ray interactions at high energies. While already being investigated at GeVenergies over several decades, assessments of diffuse gamma-ray emission at TeVenergies remain sparse. After completion of the systematic survey of the inner Galaxy, the H.E.S.S. experiment is in a prime position to observe large-scale diffuse emission at TeVenergies. Data of the H.E.S.S. Galactic Plane Survey are investigated in regions off known gamma-ray sources. Corresponding gamma-ray flux measurements were made over an extensive grid of celestial locations. Longitudinal and latitudinal profiles of the observed gamma-ray fluxes show characteristic excess emission not attributable to known gamma-ray sources. For the first time large-scale gamma-ray emission along the Galactic plane using imaging atmospheric Cherenkov telescopes has been observed. While the background subtraction technique limits the ability to recover modest variation on the scale of the H.E.S.S. field of view or larger, which is characteristic of the inverse Compton scatter-induced Galactic diffuse emission, contributions of neutral pion decay as well as emission from unresolved gamma-ray sources can be recovered in the observed signal to a large fraction. Calculations show that the minimum gamma-ray emission from pi(0) decay represents a significant contribution to the total signal. This detection is interpreted as a mix of diffuse Galactic gamma-ray emission and unresolved sources.
Y1 - 2014
U6 - https://doi.org/10.1103/PhysRevD.90.122007
SN - 1550-7998
SN - 1550-2368
VL - 90
IS - 12
PB - American Physical Society
CY - College Park
ER -
TY - JOUR
A1 - Actis, M.
A1 - Agnetta, G.
A1 - Aharonian, Felix A.
A1 - Akhperjanian, A. G.
A1 - Aleksic, J.
A1 - Aliu, E.
A1 - Allan, D.
A1 - Allekotte, I.
A1 - Antico, F.
A1 - Antonelli, L. A.
A1 - Antoranz, P.
A1 - Aravantinos, A.
A1 - Arlen, T.
A1 - Arnaldi, H.
A1 - Artmann, S.
A1 - Asano, K.
A1 - Asorey, H. G.
A1 - Baehr, J.
A1 - Bais, A.
A1 - Baixeras, C.
A1 - Bajtlik, S.
A1 - Balis, D.
A1 - Bamba, A.
A1 - Barbier, C.
A1 - Barcelo, M.
A1 - Barnacka, Anna
A1 - Barnstedt, Jürgen
A1 - de Almeida, U. Barres
A1 - Barrio, J. A.
A1 - Basso, S.
A1 - Bastieri, D.
A1 - Bauer, C.
A1 - Becerra Gonzalez, J.
A1 - Becherini, Yvonne
A1 - Bechtol, K. C.
A1 - Becker, J.
A1 - Beckmann, Volker
A1 - Bednarek, W.
A1 - Behera, B.
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A1 - Belluso, M.
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A1 - Bernardino, T.
A1 - Bernlöhr, K.
A1 - Biland, A.
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A1 - Bird, T.
A1 - Birsin, E.
A1 - Bissaldi, E.
A1 - Blake, S.
A1 - Blanch Bigas, O.
A1 - Bobkov, A. A.
A1 - Bogacz, L.
A1 - Bogdan, M.
A1 - Boisson, Catherine
A1 - Boix Gargallo, J.
A1 - Bolmont, J.
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A1 - Borkowski, Janett
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A1 - Bouvier, A.
A1 - Brau-Nogue, S.
A1 - Braun, I.
A1 - Bretz, T.
A1 - Briggs, M. S.
A1 - Brun, Pierre
A1 - Brunetti, L.
A1 - Buckley, H.
A1 - Bugaev, V.
A1 - Buehler, R.
A1 - Bulik, Tomasz
A1 - Busetto, G.
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A1 - Carr, John
A1 - Carton, P. H.
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A1 - Castarede, H.
A1 - Catalano, O.
A1 - Cavazzani, S.
A1 - Cazaux, S.
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A1 - Chadwick, M.
A1 - Chiang, J.
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A1 - Clerc, C.
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A1 - Conconi, P.
A1 - Connaughton, V.
A1 - Conrad, Jan
A1 - Contreras, J. L.
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A1 - Corona, P.
A1 - Corpace, O.
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A1 - Cotter, G.
A1 - Courty, B.
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A1 - Covino, S.
A1 - Croston, J.
A1 - Cusumano, G.
A1 - Daniel, M. K.
A1 - Dazzi, F.
A1 - Deangelis, A.
A1 - de Cea del Pozo, E.
A1 - Dal Pino, E. M. de Gouveia
A1 - de Jager, O.
A1 - de la Calle Perez, I.
A1 - De La Vega, G.
A1 - De Lotto, B.
A1 - de Naurois, M.
A1 - Wilhelmi, E. de Ona
A1 - de Souza, V.
A1 - Decerprit, B.
A1 - Deil, C.
A1 - Delagnes, E.
A1 - Deleglise, G.
A1 - Delgado, C.
A1 - Dettlaff, T.
A1 - Di Paolo, A.
A1 - Di Pierro, F.
A1 - Diaz, C.
A1 - Dick, J.
A1 - Dickinson, H.
A1 - Digel, S. W.
A1 - Dimitrov, D.
A1 - Disset, G.
A1 - Djannati-Ataï, A.
A1 - Doert, M.
A1 - Domainko, W.
A1 - Dorner, D.
A1 - Doro, M.
A1 - Dournaux, J. -L.
A1 - Dravins, D.
A1 - Drury, L.
A1 - Dubois, F.
A1 - Dubois, R.
A1 - Dubus, G.
A1 - Dufour, C.
A1 - Durand, D.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edy, E.
A1 - Egberts, Kathrin
A1 - Eleftheriadis, C.
A1 - Elles, S.
A1 - Emmanoulopoulos, D.
A1 - Enomoto, R.
A1 - Ernenwein, J. -P.
A1 - Errando, M.
A1 - Etchegoyen, A.
A1 - Falcone, A. D.
A1 - Farakos, K.
A1 - Farnier, C.
A1 - Federici, S.
A1 - Feinstein, F.
A1 - Ferenc, D.
A1 - Fillin-Martino, E.
A1 - Fink, D.
A1 - Finley, C.
A1 - Finley, J. P.
A1 - Firpo, R.
A1 - Florin, D.
A1 - Foehr, C.
A1 - Fokitis, E.
A1 - Font, Ll.
A1 - Fontaine, G.
A1 - Fontana, A.
A1 - Foerster, A.
A1 - Fortson, L.
A1 - Fouque, N.
A1 - Fransson, C.
A1 - Fraser, G. W.
A1 - Fresnillo, L.
A1 - Fruck, C.
A1 - Fujita, Y.
A1 - Fukazawa, Y.
A1 - Funk, S.
A1 - Gaebele, W.
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A1 - Garcia, B.
A1 - Garcia Lopez, R. J.
A1 - Garrido, D.
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A1 - Gascon, D.
A1 - Gasq, C.
A1 - Gaug, M.
A1 - Gaweda, J.
A1 - Geffroy, N.
A1 - Ghag, C.
A1 - Ghedina, A.
A1 - Ghigo, M.
A1 - Gianakaki, E.
A1 - Giarrusso, S.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Giro, E.
A1 - Giubilato, P.
A1 - Glanzman, T.
A1 - Glicenstein, J. -F.
A1 - Gochna, M.
A1 - Golev, V.
A1 - Gomez Berisso, M.
A1 - Gonzalez, A.
A1 - Gonzalez, F.
A1 - Granena, F.
A1 - Graciani, R.
A1 - Granot, J.
A1 - Gredig, R.
A1 - Green, A.
A1 - Greenshaw, T.
A1 - Grimm, O.
A1 - Grube, J.
A1 - Grudzinska, M.
A1 - Grygorczuk, J.
A1 - Guarino, V.
A1 - Guglielmi, L.
A1 - Guilloux, F.
A1 - Gunji, S.
A1 - Gyuk, G.
A1 - Hadasch, D.
A1 - Haefner, D.
A1 - Hagiwara, R.
A1 - Hahn, J.
A1 - Hallgren, A.
A1 - Hara, S.
A1 - Hardcastle, M. J.
A1 - Hassan, T.
A1 - Haubold, T.
A1 - Hauser, M.
A1 - Hayashida, M.
A1 - Heller, R.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Herrero, A.
A1 - Hinton, James Anthony
A1 - Hoffmann, D.
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Horns, D.
A1 - Hrupec, D.
A1 - Huan, H.
A1 - Huber, B.
A1 - Huet, J. -M.
A1 - Hughes, G.
A1 - Hultquist, K.
A1 - Humensky, T. B.
A1 - Huppert, J. -F.
A1 - Ibarra, A.
A1 - Illa, J. M.
A1 - Ingjald, J.
A1 - Inoue, S.
A1 - Inoue, Y.
A1 - Ioka, K.
A1 - Jablonski, C.
A1 - Jacholkowska, A.
A1 - Janiak, M.
A1 - Jean, P.
A1 - Jensen, H.
A1 - Jogler, T.
A1 - Jung, I.
A1 - Kaaret, P.
A1 - Kabuki, S.
A1 - Kakuwa, J.
A1 - Kalkuhl, C.
A1 - Kankanyan, R.
A1 - Kapala, M.
A1 - Karastergiou, A.
A1 - Karczewski, M.
A1 - Karkar, S.
A1 - Karlsson, N.
A1 - Kasperek, J.
A1 - Katagiri, H.
A1 - Katarzynski, K.
A1 - Kawanaka, N.
A1 - Kedziora, B.
A1 - Kendziorra, E.
A1 - Khelifi, B.
A1 - Kieda, D.
A1 - Kifune, T.
A1 - Kihm, T.
A1 - Klepser, S.
A1 - Kluzniak, W.
A1 - Knapp, J.
A1 - Knappy, A. R.
A1 - Kneiske, T.
A1 - Knoedlseder, J.
A1 - Koeck, F.
A1 - Kodani, K.
A1 - Kohri, K.
A1 - Kokkotas, K.
A1 - Komin, N.
A1 - Konopelko, A.
A1 - Kosack, K.
A1 - Kossakowski, R.
A1 - Kostka, P.
A1 - Kotula, J.
A1 - Kowal, G.
A1 - Koziol, J.
A1 - Kraehenbuehl, T.
A1 - Krause, J.
A1 - Krawczynski, H.
A1 - Krennrich, F.
A1 - Kretzschmann, A.
A1 - Kubo, H.
A1 - Kudryavtsev, V. A.
A1 - Kushida, J.
A1 - La Barbera, N.
A1 - La Parola, V.
A1 - La Rosa, G.
A1 - Lopez, A.
A1 - Lamanna, G.
A1 - Laporte, P.
A1 - Lavalley, C.
A1 - Le Flour, T.
A1 - Le Padellec, A.
A1 - Lenain, J. -P.
A1 - Lessio, L.
A1 - Lieunard, B.
A1 - Lindfors, E.
A1 - Liolios, A.
A1 - Lohse, T.
A1 - Lombardi, S.
A1 - Lopatin, A.
A1 - Lorenz, E.
A1 - Lubinski, P.
A1 - Luz, O.
A1 - Lyard, E.
A1 - Maccarone, M. C.
A1 - Maccarone, T.
A1 - Maier, G.
A1 - Majumdar, P.
A1 - Maltezos, S.
A1 - Malkiewicz, P.
A1 - Mana, C.
A1 - Manalaysay, A.
A1 - Maneva, G.
A1 - Mangano, A.
A1 - Manigot, P.
A1 - Marin, J.
A1 - Mariotti, M.
A1 - Markoff, S.
A1 - Martinez, G.
A1 - Martinez, M.
A1 - Mastichiadis, A.
A1 - Matsumoto, H.
A1 - Mattiazzo, S.
A1 - Mazin, D.
A1 - McComb, T. J. L.
A1 - McCubbin, N.
A1 - McHardy, I.
A1 - Medina, C.
A1 - Melkumyan, D.
A1 - Mendes, A.
A1 - Mertsch, P.
A1 - Meucci, M.
A1 - Michalowski, J.
A1 - Micolon, P.
A1 - Mineo, T.
A1 - Mirabal, N.
A1 - Mirabel, F.
A1 - Miranda, J. M.
A1 - Mirzoyan, R.
A1 - Mizuno, T.
A1 - Moal, B.
A1 - Moderski, R.
A1 - Molinari, E.
A1 - Monteiro, I.
A1 - Moralejo, A.
A1 - Morello, C.
A1 - Mori, K.
A1 - Motta, G.
A1 - Mottez, F.
A1 - Moulin, Emmanuel
A1 - Mukherjee, R.
A1 - Munar, P.
A1 - Muraishi, H.
A1 - Murase, K.
A1 - Murphy, A. Stj.
A1 - Nagataki, S.
A1 - Naito, T.
A1 - Nakamori, T.
A1 - Nakayama, K.
A1 - Naumann, C. L.
A1 - Naumann, D.
A1 - Nayman, P.
A1 - Nedbal, D.
A1 - Niedzwiecki, A.
A1 - Niemiec, J.
A1 - Nikolaidis, A.
A1 - Nishijima, K.
A1 - Nolan, S. J.
A1 - Nowak, N.
A1 - O'Brien, P. T.
A1 - Ochoa, I.
A1 - Ohira, Y.
A1 - Ohishi, M.
A1 - Ohka, H.
A1 - Okumura, A.
A1 - Olivetto, C.
A1 - Ong, R. A.
A1 - Orito, R.
A1 - Orr, M.
A1 - Osborne, J. P.
A1 - Ostrowski, M.
A1 - Otero, L.
A1 - Otte, A. N.
A1 - Ovcharov, E.
A1 - Oya, I.
A1 - Ozieblo, A.
A1 - Paiano, S.
A1 - Pallota, J.
A1 - Panazol, J. L.
A1 - Paneque, D.
A1 - Panter, M.
A1 - Paoletti, R.
A1 - Papyan, G.
A1 - Paredes, J. M.
A1 - Pareschi, G.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pedaletti, G.
A1 - Pepato, A.
A1 - Persic, M.
A1 - Petrucci, P. O.
A1 - Peyaud, B.
A1 - Piechocki, W.
A1 - Pita, S.
A1 - Pivato, G.
A1 - Platos, L.
A1 - Platzer, R.
A1 - Pogosyan, L.
A1 - Pohl, Martin
A1 - Pojmanski, G.
A1 - Ponz, J. D.
A1 - Potter, W.
A1 - Prandini, E.
A1 - Preece, R.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quel, E.
A1 - Quirrenbach, A.
A1 - Rajda, P.
A1 - Rando, R.
A1 - Rataj, M.
A1 - Raue, M.
A1 - Reimann, C.
A1 - Reimann, O.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - Renner, S.
A1 - Reymond, J. -M.
A1 - Rhode, W.
A1 - Ribo, M.
A1 - Ribordy, M.
A1 - Rico, J.
A1 - Rieger, F.
A1 - Ringegni, P.
A1 - Ripken, J.
A1 - Ristori, P.
A1 - Rivoire, S.
A1 - Rob, L.
A1 - Rodriguez, S.
A1 - Roeser, U.
A1 - Romano, Patrizia
A1 - Romero, G. E.
A1 - Rosier-Lees, S.
A1 - Rovero, A. C.
A1 - Roy, F.
A1 - Royer, S.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Ruppel, J.
A1 - Russo, F.
A1 - Ryde, F.
A1 - Sacco, B.
A1 - Saggion, A.
A1 - Sahakian, V.
A1 - Saito, K.
A1 - Saito, T.
A1 - Sakaki, N.
A1 - Salazar, E.
A1 - Salini, A.
A1 - Sanchez, F.
A1 - Sanchez Conde, M. A.
A1 - Santangelo, Andrea
A1 - Santos, E. M.
A1 - Sanuy, A.
A1 - Sapozhnikov, L.
A1 - Sarkar, S.
A1 - Scalzotto, V.
A1 - Scapin, V.
A1 - Scarcioffolo, M.
A1 - Schanz, T.
A1 - Schlenstedt, S.
A1 - Schlickeiser, R.
A1 - Schmidt, T.
A1 - Schmoll, J.
A1 - Schroedter, M.
A1 - Schultz, C.
A1 - Schultze, J.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schweizer, T.
A1 - Seiradakis, J.
A1 - Selmane, S.
A1 - Seweryn, K.
A1 - Shayduk, M.
A1 - Shellard, R. C.
A1 - Shibata, T.
A1 - Sikora, M.
A1 - Silk, J.
A1 - Sillanpaa, A.
A1 - Sitarek, J.
A1 - Skole, C.
A1 - Smith, N.
A1 - Sobczynska, D.
A1 - Sofo Haro, M.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spiga, D.
A1 - Spyrou, S.
A1 - Stamatescu, V.
A1 - Stamerra, A.
A1 - Starling, R. L. C.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Steiner, S.
A1 - Stergioulas, N.
A1 - Sternberger, R.
A1 - Stinzing, F.
A1 - Stodulski, M.
A1 - Straumann, U.
A1 - Suarez, A.
A1 - Suchenek, M.
A1 - Sugawara, R.
A1 - Sulanke, K. H.
A1 - Sun, S.
A1 - Supanitsky, A. D.
A1 - Sutcliffe, P.
A1 - Szanecki, M.
A1 - Szepieniec, T.
A1 - Szostek, A.
A1 - Szymkowiak, A.
A1 - Tagliaferri, G.
A1 - Tajima, H.
A1 - Takahashi, H.
A1 - Takahashi, K.
A1 - Takalo, L.
A1 - Takami, H.
A1 - Talbot, R. G.
A1 - Tam, P. H.
A1 - Tanaka, M.
A1 - Tanimori, T.
A1 - Tavani, M.
A1 - Tavernet, J. -P.
A1 - Tchernin, C.
A1 - Tejedor, L. A.
A1 - Telezhinsky, Igor O.
A1 - Temnikov, P.
A1 - Tenzer, C.
A1 - Terada, Y.
A1 - Terrier, R.
A1 - Teshima, M.
A1 - Testa, V.
A1 - Tibaldo, L.
A1 - Tibolla, O.
A1 - Tluczykont, M.
A1 - Peixoto, C. J. Todero
A1 - Tokanai, F.
A1 - Tokarz, M.
A1 - Toma, K.
A1 - Torres, D. F.
A1 - Tosti, G.
A1 - Totani, T.
A1 - Toussenel, F.
A1 - Vallania, P.
A1 - Vallejo, G.
A1 - van der Walt, J.
A1 - van Eldik, C.
A1 - Vandenbroucke, J.
A1 - Vankov, H.
A1 - Vasileiadis, G.
A1 - Vassiliev, V. V.
A1 - Vegas, I.
A1 - Venter, L.
A1 - Vercellone, S.
A1 - Veyssiere, C.
A1 - Vialle, J. P.
A1 - Videla, M.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Vlahakis, N.
A1 - Vlahos, L.
A1 - Vogler, P.
A1 - Vollhardt, A.
A1 - Volpe, F.
A1 - Von Gunten, H. P.
A1 - Vorobiov, S.
A1 - Wagner, S.
A1 - Wagner, R. M.
A1 - Wagner, B.
A1 - Wakely, S. P.
A1 - Walter, P.
A1 - Walter, R.
A1 - Warwick, R.
A1 - Wawer, P.
A1 - Wawrzaszek, R.
A1 - Webb, N.
A1 - Wegner, P.
A1 - Weinstein, A.
A1 - Weitzel, Q.
A1 - Welsing, R.
A1 - Wetteskind, H.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Wilkinson, M. I.
A1 - Williams, D. A.
A1 - Winde, M.
A1 - Wischnewski, R.
A1 - Wisniewski, L.
A1 - Wolczko, A.
A1 - Wood, M.
A1 - Xiong, Q.
A1 - Yamamoto, T.
A1 - Yamaoka, K.
A1 - Yamazaki, R.
A1 - Yanagita, S.
A1 - Yoffo, B.
A1 - Yonetani, M.
A1 - Yoshida, A.
A1 - Yoshida, T.
A1 - Yoshikoshi, T.
A1 - Zabalza, V.
A1 - Zagdanski, A.
A1 - Zajczyk, A.
A1 - Zdziarski, A.
A1 - Zech, Alraune
A1 - Zietara, K.
A1 - Ziolkowski, P.
A1 - Zitelli, V.
A1 - Zychowski, P.
T1 - Design concepts for the Cherenkov Telescope Array CTA an advanced facility for ground-based high-energy gamma-ray astronomy
JF - Experimental astronomy : an international journal on astronomical instrumentation and data analysis
N2 - Ground-based gamma-ray astronomy has had a major breakthrough with the impressive results obtained using systems of imaging atmospheric Cherenkov telescopes. Ground-based gamma-ray astronomy has a huge potential in astrophysics, particle physics and cosmology. CTA is an international initiative to build the next generation instrument, with a factor of 5-10 improvement in sensitivity in the 100 GeV-10 TeV range and the extension to energies well below 100 GeV and above 100 TeV. CTA will consist of two arrays (one in the north, one in the south) for full sky coverage and will be operated as open observatory. The design of CTA is based on currently available technology. This document reports on the status and presents the major design concepts of CTA.
KW - Ground based gamma ray astronomy
KW - Next generation Cherenkov telescopes
KW - Design concepts
Y1 - 2011
U6 - https://doi.org/10.1007/s10686-011-9247-0
SN - 0922-6435
SN - 1572-9508
VL - 32
IS - 3
SP - 193
EP - 316
PB - Springer
CY - Dordrecht
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Andersson, T.
A1 - Anguener, O.
A1 - Arrieta, M.
A1 - Aubert, P.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Boettcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Carr, J.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Decock, J.
A1 - Degrange, B.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M. -H.
A1 - Hadasch, D.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Settimo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywucka, N.
A1 - Katsuta, J.
T1 - The supernova remnant W49B as seen with HESS and Fermi-LAT
JF - Astronomy and astrophysics : an international weekly journal
N2 - The supernova remnant (SNR) W49B originated from a core-collapse supernova that occurred between one and four thousand years ago, and subsequently evolved into a mixed-morphology remnant, which is interacting with molecular clouds (MC). Gamma-ray observations of SNR-MC associations are a powerful tool to constrain the origin of Galactic cosmic rays, as they can probe the acceleration of hadrons through their interaction with the surrounding medium and subsequent emission of non-thermal photons. We report the detection of a gamma-ray source coincident with W49B at very high energies (VHE; E > 100 GeV) with the H.E.S.S. Cherenkov telescopes together with a study of the source with five years of Fermi-LAT high-energy gamma-ray (0.06-300 GeV) data. The smoothly connected, combined source spectrum, measured from 60 MeV to multi-TeV energies, shows two significant spectral breaks at 304 +/- 20 MeV and 8.4(-2.5)(+2.5) GeV; the latter is constrained by the joint fit from the two instruments. The detected spectral features are similar to those observed in several other SNR-MC associations and are found to be indicative of gamma-ray emission produced through neutral-pion decay.
KW - gamma rays: general
KW - ISM: supernova remnants
KW - ISM: clouds
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201527843
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Andersson, T.
A1 - Anguener, E. O.
A1 - Arakawa, M.
A1 - Arrieta, M.
A1 - Aubert, P.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Boettcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Bilchele, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Carr, J.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Coffaro, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Decock, J.
A1 - Degrange, B.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goya, A.
A1 - Grondin, M. -H.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Iwasaki, H.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitche, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Richter, S.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Saito, S.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Settimo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Takahashi, T.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywucka, N.
T1 - Deeper HESS observations of Vela Junior (RX J0852.0-4622)
BT - Morphology studies and resolved spectroscopy
JF - Astronomy and astrophysics : an international weekly journal
N2 - Aims. We study gamma-ray emission from the shell-type supernova remnant (SNR) RXJ0852.0-4622 to better characterize its spectral properties and its distribution over the SNR. Methods. The analysis of an extended High Energy Spectroscopic System (H.E.S.S.) data set at very high energies (E > 100 GeV) permits detailed studies, as well as spatially resolved spectroscopy, of the morphology and spectrum of the whole RXJ0852.0-4622 region. The H.E.S.S. data are combined with archival data from other wavebands and interpreted in the framework of leptonic and hadronic models. The joint Fermi-LAT-H.E.S.S. spectrum allows the direct determination of the spectral characteristics of the parent particle population in leptonic and hadronic scenarios using only GeV-TeV data. Results. An updated analysis of the H.E.S.S. data shows that the spectrum of the entire SNR connects smoothly to the high-energy spectrum measured by Fermi-LAT. The increased data set makes it possible to demonstrate that the H.E.S.S. spectrum deviates significantly from a power law and is well described by both a curved power law and a power law with an exponential cutoff at an energy of E-cut = (6.7 +/- 1.2(stat) +/- 1.2(syst)) TeV. The joint Fermi-LAT-H.E.S.S. spectrum allows the unambiguous identification of the spectral shape as a power law with an exponential cutoff. No significant evidence is found for a variation of the spectral parameters across the SNR, suggesting similar conditions of particle acceleration across the remnant. A simple modeling using one particle population to model the SNR emission demonstrates that both leptonic and hadronic emission scenarios remain plausible. It is also shown that at least a part of the shell emission is likely due to the presence of a pulsar wind nebula around PSR J0855-4644.
KW - astroparticle physics
KW - gamma rays: general
KW - acceleration of particles
KW - cosmic rays
KW - ISM: supernova remnants
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201630002
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Angüner, Ekrem Oǧuzhan
A1 - Arakawa, M.
A1 - Armand, C.
A1 - Arrieta, M.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Boettcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bonnefoy, S.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Buechele, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Caroff, S.
A1 - Carosi, A.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Colafrancesco, S.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Davids, I. D.
A1 - Decock, J.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Donath, A.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Emery, G.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Gate, F.
A1 - Giavitto, G.
A1 - Glawion, D.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M. -H.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holch, T. L.
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Iwasaki, H.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Kruger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lefaucheur, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Malyshev, D.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Ndiyavala, H.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poireau, V.
A1 - Prokhorov, D. A.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Rauth, R.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Rinchiuso, L.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Saito, S.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Shiningayamwe, K.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spir-Jacob, M.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Steppa, Constantin Beverly
A1 - Sushch, I.
A1 - Takahashi, T.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsirou, M.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zorn, J.
A1 - Zywucka, N.
A1 - Enokiya, R.
A1 - Fukui, Y.
A1 - Hayakawa, T.
A1 - Okuda, T.
A1 - Torii, K.
A1 - Yamamoto, H.
T1 - HESS J1741-302: a hidden accelerator in the Galactic plane
JF - Astronomy and astrophysics : an international weekly journal
N2 - The H.E.S.S. Collaboration has discovered a new very high energy (VHE, E > 0.1 TeV) gamma-ray source, HESS J1741-302, located in the Galactic plane. Despite several attempts to constrain its nature, no plausible counterpart has been found so far at X-ray and MeV/GeV gamma-ray energies, and the source remains unidentified. An analysis of 145-h of observations of HESS J1741-302 at VHEs has revealed a steady and relatively weak TeV source (similar to 1% of the Crab Nebula flux), with a spectral index of Gamma = 2.3 +/- 0.2(stat) +/- 0.2(sys), extending to energies up to 10 TeV without any clear signature of a cut-off. In a hadronic scenario, such a spectrum implies an object with particle acceleration up to energies of several hundred TeV. Contrary to most H.E.S.S. unidentified sources, the angular size of HESS J1741-302 is compatible with the H.E.S.S. point spread function at VHEs, with an extension constrained to be below 0.068 degrees at a 99% confidence level. The gamma-ray emission detected by H.E.S.S. can be explained both within a hadronic scenario, due to collisions of protons with energies of hundreds of TeV with dense molecular clouds, and in a leptonic scenario, as a relic pulsar wind nebula, possibly powered by the middle-aged (20 kyr) pulsar PSR B1737-30. A binary scenario, related to the compact radio source 1LC 358.266+0.038 found to be spatially coincident with the best fit position of HESS J1741-302, is also envisaged.
KW - gamma rays: ISM
KW - gamma rays: general
KW - cosmic rays
KW - ISM: clouds
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201730581
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Andersson, T.
A1 - Anguener, E. O.
A1 - Arakawa, M.
A1 - Arrieta, M.
A1 - Aubert, P.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Bottcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Buechele, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Carr, J.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Coffaro, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Decock, J.
A1 - Degrange, B.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M. -H.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Iwasaki, H.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Kruger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Richter, S.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Saito, S.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Settimo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian Michael
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Takahashi, T.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywucka, N.
T1 - Systematic search for very-high-energy gamma-ray emission from bow shocks of runaway stars
JF - Astronomy and astrophysics : an international weekly journal
N2 - Context. Runaway stars form bow shocks by ploughing through the interstellar medium at supersonic speeds and are promising sources of non-thermal emission of photons. One of these objects has been found to emit non-thermal radiation in the radio band. This triggered the development of theoretical models predicting non-thermal photons from radio up to very-high-energy (VHE, E >= 0.1 TeV) gamma rays. Subsequently, one bow shock was also detected in X-ray observations. However, the data did not allow discrimination between a hot thermal and a non-thermal origin. Further observations of different candidates at X-ray energies showed no evidence for emission at the position of the bow shocks either. A systematic search in the Fermi-LAT energy regime resulted in flux upper limits for 27 candidates listed in the E-BOSS catalogue. Aims. Here we perform the first systematic search for VHE gamma-ray emission from bow shocks of runaway stars. Methods. Using all available archival H.E.S.S. data we search for very-high-energy gamma-ray emission at the positions of bow shock candidates listed in the second E-BOSS catalogue release. Out of the 73 bow shock candidates in this catalogue, 32 have been observed with H.E.S.S. Results. None of the observed 32 bow shock candidates in this population study show significant emission in the H.E.S.S. energy range. Therefore, flux upper limits are calculated in five energy bins and the fraction of the kinetic wind power that is converted into VHE gamma rays is constrained. Conclusions. Emission from stellar bow shocks is not detected in the energy range between 0.14 and 18 TeV. The resulting upper limits constrain the level of VHE gamma-ray emission from these objects down to 0.1-1% of the kinetic wind energy.
KW - radiation mechanisms: non-thermal
KW - gamma rays: ISM
KW - stars: early-type
KW - gamma rays: stars
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201630151
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Andersson, T.
A1 - Anguener, E. O.
A1 - Arakawa, M.
A1 - Arrieta, M.
A1 - Aubert, P.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Boettcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bonnefoy, S.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Buechele, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Carr, J.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Coffaro, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Decock, J.
A1 - Degrange, B.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M. -H.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holch, T. L.
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Iwasaki, H.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitche, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Richter, S.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Saito, S.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Settimo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Takahashi, T.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Wale, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywucka, N.
A1 - Bamba, A.
A1 - Fukui, Y.
A1 - Sano, H.
A1 - Yoshiike, S.
T1 - A search for new supernova remnant shells in the Galactic plane with HESS
JF - Astronomy and astrophysics : an international weekly journal
N2 - A search for new supernova remnants (SNRs) has been conducted using TeV gamma-ray data from the H.E.S.S. Galactic plane survey. As an identification criterion, shell morphologies that are characteristic for known resolved TeV SNRs have been used. Three new SNR candidates were identified in the H.E.S.S. data set with this method. Extensive multiwavelength searches for counterparts were conducted. A radio SNR candidate has been identified to be a counterpart to HESS J1534-571. The TeV source is therefore classified as a SNR. For the other two sources, HESS J1614-518 and HESS J1912 + 101, no identifying counterparts have been found, thus they remain SNR candidates for the time being. TeV-emitting SNRs are key objects in the context of identifying the accelerators of Galactic cosmic rays. The TeV emission of the relativistic particles in the new sources is examined in view of possible leptonic and hadronic emission scenarios, taking the current multiwavelength knowledge into account.
KW - astroparticle physics
KW - ISM: supernova remnants
KW - cosmic rays
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201730737
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Anguener, E. O.
A1 - Arrieta, M.
A1 - Aubert, P.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Birsin, E.
A1 - Blackwell, R.
A1 - Bottcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Carr, J.
A1 - Casanova, Sabrina
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Hadasch, D.
A1 - Hahn, J.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Krayzel, F.
A1 - Kruger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, E.
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tuffs, R.
A1 - van der Walt, J.
A1 - van Eldik, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywucka, N.
T1 - Extended VHE gamma-ray emission towards SGR1806-20, LBV 1806-20, and stellar cluster Cl*1806-20
JF - Astronomy and astrophysics : an international weekly journal
N2 - Using the High Energy Spectroscopic System (H.E.S.S.) telescopes we have discovered a steady and extended very high-energy (VHE) gamma-ray source towards the luminous blue variable candidate LBV 1806-20, massive stellar cluster Cl* 1806-20, and magnetar SGR 1806-20. The new VHE source, HESS J1808-204, was detected at a statistical significance of >6 sigma (post-trial) with a photon flux normalisation (2.9 +/- 0.4(stat) +/- 0.5(sys)) x 10(-13) ph cm(-2) s(-1) TeV-1 at 1 TeV and a power-law photon index of 2.3 +/- 0.2(stat) +/- 0.3(sys). The luminosity of this source (0.2 to 10 TeV; scaled to distance d = 8 : 7 kpc) is L-VHE similar to 1.6 x 10(34)(d = 8.7 kpc)(2) erg s(-1). The VHE gamma-ray emission is extended and is well fit by a single Gaussian with statistical standard deviation of 0.095 degrees +/- 0.015 degrees. This extension is similar to that of the synchrotron radio nebula G10.0-0.3, which is thought to be powered by LBV 1806-20. The VHE gamma-ray luminosity could be provided by the stellar wind luminosity of LBV 1806-20 by itself and/or the massive star members of Cl* 1806-20. Alternatively, magnetic dissipation (e.g. via reconnection) from SGR 1806-20 can potentially account for the VHE luminosity. The origin and hadronic and/or leptonic nature of the accelerated particles responsible for HESS J1808-204 is not yet clear. If associated with SGR 1806 20, the potentially young age of the magnetar (650 yr) can be used to infer the transport limits of these particles to match the VHE source size. This discovery provides new interest in the potential for high-energy particle acceleration from magnetars, massive stars, and/or stellar clusters.
KW - gamma rays: general
KW - stars: magnetars
KW - stars: massive
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201628695
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Andersson, T.
A1 - Anguener, E. O.
A1 - Arrieta, M.
A1 - Aubert, P.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Boettcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Carr, J.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Decock, J.
A1 - Degrange, B.
A1 - Dei, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fukuyama, T.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M. -H.
A1 - Hadasch, D.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Settimo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanie, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Takahashi, T.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Edik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywucka, N.
T1 - HESS observations of RX J1713.7-3946 with improved angular and spectral resolution
BT - Evidence for gamma-ray emission extending beyond the X-ray emitting shell
JF - Astronomy and astrophysics : an international weekly journal
KW - acceleration of particles
KW - cosmic rays
KW - ISM: supernova remnants
KW - gamma rays: general
KW - astroparticle physic
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201629790
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Backes, Michael
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Berge, David
A1 - Bernhard, Sabrina
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Biteau, Jonathan
A1 - Böttcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, Johan
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bryan, Mark
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Chadwick, Paula M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Dalton, M.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - dewilt, P.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Forster, A.
A1 - Fuling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Hadsch, D.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Harris, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, Markus
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kiefeer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Kruger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - McComb, T. J. L.
A1 - Mehault, J.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perez, J.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Puhlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reichardt, I.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Rob, L.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - Van Eldik, C.
A1 - Van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Volk, H. J.
A1 - Volpe, F.
A1 - Vorster, M.
A1 - Vuillaume, T.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - Ward, M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Wornlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. -S.
T1 - Long-term monitoring of PKS2155-304 with ATOM and HESS:investigation of optical/gamma-ray correlations in different spectral states
JF - Astronomy and astrophysics : an international weekly journal
N2 - In this paper we report on the analysis of all the available optical and very high-energy gamma-ray (> 200 GeV) data for the BL Lac object PKS 2155-304, collected simultaneously with the ATOM and H.E.S.S. telescopes from 2007 until 2009. This study also includes X-ray (RXTE, Swift) and high-energy gamma-ray (Fermi-LAT) data. During the period analysed, the source was transitioning from its flaring to quiescent optical states, and was characterized by only moderate flux changes at different wavelengths on the timescales of days and months. A flattening of the optical continuum with an increasing optical flux can be noted in the collected dataset, but only occasionally and only at higher flux levels. We did not find any universal relation between the very high-energy gamma-ray and optical flux changes on the timescales from days and weeks up to several years. On the other hand, we noted that at higher flux levels the source can follow two distinct tracks in the optical flux-colour diagrams, which seem to be related to distinct gamma-ray states of the blazar. The obtained results therefore indicate a complex scaling between the optical and gamma-ray emission of PKS 2155 304, with different correlation patterns holding at different epochs, and a gamma-ray flux depending on the combination of an optical flux and colour rather than a flux alone.
KW - radiation mechanisms: non-thermal
KW - galaxies: active
KW - black hole physics
KW - BL Lacertae objects: individual: PKS 2155-304
KW - galaxies: jets
KW - gamma rays: galaxies
Y1 - 2014
U6 - https://doi.org/10.1051/0004-6361/201424142
SN - 0004-6361
SN - 1432-0746
VL - 571
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Backes, Michael
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Berge, David
A1 - Bernhard, Sabrina
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Biteau, Jonathan
A1 - Boettcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, Johan
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bryan, Mark
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Chadwick, Paula M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Füssling, Matthias
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Hadasch, D.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Harris, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, Maraike
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, Michael
A1 - McComb, T. J. L.
A1 - Mehault, J.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Petrucci, P. -O
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reichardt, I.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorster, M.
A1 - Vuillaume, T.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - Ward, M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. -S.
T1 - HESS reveals a lack of TeV emission from the supernova remnant Puppis A (Research Note)
JF - Astronomy and astrophysics : an international weekly journal
N2 - Context. Puppis A is an interesting similar to 4 kyr-old supernova remnant (SNR) that shows strong evidence of interaction between the forward shock and a molecular cloud. It has been studied in detail from radio frequencies to high-energy (HE, 0.1-100 GeV) gamma-rays. An analysis of the Fermi-LAT data has shown extended HE gamma-ray emission with a 0.2-100 GeV spectrum exhibiting no significant deviation from a power law, unlike most of the GeV-emitting SNRs known to be interacting with molecular clouds. This makes it a promising target for imaging atmospheric Cherenkov telescopes (IACTs) to probe the gamma-ray emission above 100 GeV.
Aims. Very-high-energy (VHE, E >= 0.1 TeV) gamma-ray emission from Puppis A has been, for the first time, searched for with the High Energy Stereoscopic System (HESS.).
Methods. Stereoscopic imaging of Cherenkov radiation from extensive air showers is used to reconstruct the direction and energy of the incident gamma-rays in order to produce sky images and source spectra. The profile likelihood method is applied to find constraints on the existence of a potential break or cutoff in the photon spectrum.
Results. The analysis of the HESS. data does not reveal any significant emission towards Puppis A. The derived upper limits on the differential photon flux imply that its broadband gamma-ray spectrum must exhibit a spectral break or cutoff. By combining Fermi-LAT and HESS. measurements, the 99% confidence-level upper limits on such a cutoff are found to be 450 and 280 GeV, assuming a power law with a simple exponential and a sub-exponential cutoff, respectively. It is concluded that none of the standard limitations (age, size, radiative losses) on the particle acceleration mechanism, assumed to be continuing at present, can explain the lack of VHE signal. The scenario in which particle acceleration has ceased some time ago is considered as an alternative explanation. The HE/VHE spectrum of Puppis A could then exhibit a break of non-radiative origin (as observed in several other interacting SNRs, albeit at somewhat higher energies), owing to the interaction with dense and neutral material, in particular towards the NE region.
KW - gamma rays: ISM
KW - ISM: individual objects: Puppis A
KW - radiation mechanisms: non-thermal
KW - cosmic rays
KW - acceleration of particles
Y1 - 2015
U6 - https://doi.org/10.1051/0004-6361/2014424805
SN - 0004-6361
SN - 1432-0746
VL - 575
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Aliu, E.
A1 - Archambault, S.
A1 - Aune, T.
A1 - Behera, B.
A1 - Beilicke, M.
A1 - Benbow, W.
A1 - Berger, K.
A1 - Bird, R.
A1 - Bouvier, A.
A1 - Buckley, J. H.
A1 - Bugaev, V.
A1 - Byrum, K.
A1 - Cerruti, M.
A1 - Chen, X.
A1 - Ciupik, L.
A1 - Connolly, M. P.
A1 - Cui, W.
A1 - Duke, C.
A1 - Dumm, J.
A1 - Errando, M.
A1 - Falcone, A.
A1 - Federici, S.
A1 - Feng, Q.
A1 - Finley, J. P.
A1 - Fortin, P.
A1 - Fortson, L.
A1 - Furniss, A.
A1 - Galante, N.
A1 - Gillanders, G. H.
A1 - Griffin, S.
A1 - Griffiths, S. T.
A1 - Grube, J.
A1 - Gyuk, G.
A1 - Hanna, D.
A1 - Holder, J.
A1 - Hughes, G.
A1 - Humensky, T. B.
A1 - Kaaret, P.
A1 - Kertzman, M.
A1 - Khassen, Y.
A1 - Kieda, D.
A1 - Krawczynski, H.
A1 - Krennrich, F.
A1 - Lang, M. J.
A1 - Madhavan, A. S.
A1 - Maier, G.
A1 - Majumdar, P.
A1 - McCann, A.
A1 - Moriarty, P.
A1 - Mukherjee, R.
A1 - Nieto, D.
A1 - Ong, R. A.
A1 - Otte, A. N.
A1 - Park, N.
A1 - Perkins, J. S.
A1 - Pohl, M.
A1 - Popkow, A.
A1 - Prokoph, H.
A1 - Quinn, J.
A1 - Ragan, K.
A1 - Rajotte, J.
A1 - Reyes, L. C.
A1 - Reynolds, P. T.
A1 - Richards, G. T.
A1 - Roache, E.
A1 - Rousselle, J.
A1 - Sembroski, G. H.
A1 - Sheidaei, F.
A1 - Skole, C.
A1 - Smith, A. W.
A1 - Staszak, D.
A1 - Stroh, M.
A1 - Telezhinsky, Igor O.
A1 - Theiling, M.
A1 - Tucci, J. V.
A1 - Tyler, J.
A1 - Varlotta, A.
A1 - Vincent, S.
A1 - Wakely, S. P.
A1 - Weinstein, A.
A1 - Welsing, R.
A1 - Williams, D. A.
A1 - Zajczyk, A.
A1 - Zitzer, B.
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Anton, Gisela
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Bissaldi, E.
A1 - Biteau, Jonathan
A1 - Boettcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Brucker, J.
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chadwick, Paula M.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Cheesebrough, A.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Dalton, M.
A1 - Daniel, M. K.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Dickinson, H. J.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, M.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Harris, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, M.
A1 - Horns, D.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kneiske, T.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lennarz, D.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - McComb, T. J. L.
A1 - Mehault, J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Naumann, C. L.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Oakes, L.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perez, J.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Raue, M.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Rob, L.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sol, H.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Szostek, A.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, C.
A1 - Vasileiadis, G.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorster, M.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Ward, M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Zacharias, M.
A1 - Zajczyk, A.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. -S.
T1 - Long-term TeV and X-RAY observations of the GAMMA- RAY binary hess J0632+057
JF - The astrophysical journal : an international review of spectroscopy and astronomical physics
KW - acceleration of particles
KW - binaries: general
KW - gamma rays: general(HESS J0632+057, VER J0633+057)
Y1 - 2014
U6 - https://doi.org/10.1088/0004-637X/780/2/168
SN - 0004-637X
SN - 1538-4357
VL - 780
IS - 2
PB - IOP Publ. Ltd.
CY - Bristol
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Andersson, T.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Arrieta, M.
A1 - Aubert, Pierre
A1 - Backes, Michael
A1 - Balzer, Arnim
A1 - Barnard, Michelle
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Berge, David
A1 - Bernhard, Sabrina
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Blackwell, R.
A1 - Boettcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, Johan
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bryan, Mark
A1 - Bulik, Tomasz
A1 - Capasso, M.
A1 - Carr, John
A1 - Casanova, Sabrina
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Chen, Andrew
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Condon, B.
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - Devin, J.
A1 - de Wilt, P.
A1 - Djannati-Ataie, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Hadasch, D.
A1 - Hahn, J.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Liu, R.
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, Michael
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oettl, S.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - Reyes, R. de los
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Settimo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tuffs, R.
A1 - van der Walt, J.
A1 - van Eldik, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywucka, N.
T1 - HESS Limits on Linelike Dark Matter Signatures in the 100 GeV to 2 TeV Energy Range Close to the Galactic Center
JF - Physical review letters
N2 - A search for dark matter linelike signals iss performed in the vicinity of the Galactic Center by the H.E.S.S. experiment on observational data taken in 2014. An unbinned likelihood analysis iss developed to improve the sensitivity to linelike signals. The upgraded analysis along with newer data extend the energy coverage of the previous measurement down to 100 GeV. The 18 h of data collected with the H.E.S.S. array allow one to rule out at 95% C.L. the presence of a 130 GeV line (at l = -1.5 degrees, b = 0 degrees and for a dark matter profile centered at this location) previously reported in Fermi-LAT data. This new analysis overlaps significantly in energy with previous Fermi-LAT and H.E.S.S. results. No significant excess associated with dark matter annihilations was found in the energy range of 100 GeV to 2 TeV and upper limits on the gamma-ray flux and the velocity weighted annihilation cross section are derived adopting an Einasto dark matter halo profile. Expected limits for present and future large statistics H.E.S.S. observations are also given.
Y1 - 2016
U6 - https://doi.org/10.1103/PhysRevLett.117.151302
SN - 0031-9007
SN - 1079-7114
VL - 117
PB - American Physical Society
CY - College Park
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Anton, Gisela
A1 - Backes, Michael
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Bissaldi, E.
A1 - Biteau, Jonathan
A1 - Boettcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Brucker, J.
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Chadwick, Paula M.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Cheesebrough, A.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Dalton, M.
A1 - Daniel, M. K.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Dickinson, H. J.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, M.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Harris, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, M.
A1 - Horns, D.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, Uli
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kneiske, Tanja
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - McComb, T. J. L.
A1 - Mehault, J.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Naumann, C. L.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perez, J.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Raue, M.
A1 - Reichardt, I.
A1 - Reimer, A.
A1 - Reimer, Olaf
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Rob, L.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sol, H.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, Christopher
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorster, M.
A1 - Vuillaume, T.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - Ward, M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Wrnlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. -S.
A1 - Finke, J.
A1 - Fortin, P.
A1 - Horan, D.
T1 - The high-energy gamma-ray emission of AP Librae
JF - Astronomy and astrophysics : an international weekly journal
N2 - The gamma-ray spectrum of the low-frequency-peaked BL Lac (LBL) object AP Librae is studied, following the discovery of very-high-energy (VHE; E > 100 GeV) gamma-ray emission up to the TeV range by the H.E.S.S. experiment. Thismakes AP Librae one of the few VHE emitters of the LBL type. The measured spectrum yields a flux of (8.8 +/- 1.5(stat) +/- 1.8(sys)) x 10(-12) cm(-2) s(-1) above 130 GeV and a spectral index of Gamma = 2.65 +/- 0.19(stat) +/- 0.20(sys). This study also makes use of Fermi-LAT observations in the high energy (HE, E > 100 MeV) range, providing the longest continuous light curve (5 years) ever published on this source. The source underwent a flaring event between MJD 56 306-56 376 in the HE range, with a flux increase of a factor of 3.5 in the 14 day bin light curve and no significant variation in spectral shape with respect to the low-flux state. While the H.E.S.S. and (low state) Fermi-LAT fluxes are in good agreement where they overlap, a spectral curvature between the steep VHE spectrum and the Fermi-LAT spectrum is observed. The maximum of the gamma-ray emission in the spectral energy distribution is located below the GeV energy range.
KW - galaxies: active
KW - BL Lacertae objects: individual: AP Librae
KW - gamma rays: galaxies
Y1 - 2015
U6 - https://doi.org/10.1051/0004-6361/201321436
SN - 0004-6361
SN - 1432-0746
VL - 573
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Acero, F.
A1 - Aharonian, Felix A.
A1 - Akhperjanian, A. G.
A1 - Anton, Gisela
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Behera, B.
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Biteau, Jonathan
A1 - Bochow, A.
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Brucker, J.
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chadwick, Paula M.
A1 - Chaves, Ryan C. G.
A1 - Cheesebrough, A.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Dalton, M.
A1 - Daniel, M. K.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Dickinson, H. J.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Drury, L. O'C.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Fallon, L.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foester, A.
A1 - Fuessling, M.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Gast, H.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Glueck, B.
A1 - Goeing, D.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Haeffner, S.
A1 - Hague, J. D.
A1 - Hahn, J.
A1 - Hampf, D.
A1 - Harris, J.
A1 - Hauser, M.
A1 - Heinz, S.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, Markus
A1 - Horns, D.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Jung, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kneiske, T.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Kossakowski, R.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lennarz, D.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Masbou, J.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - McComb, T. J. L.
A1 - Medina, M. C.
A1 - Mehault, J.
A1 - Menzler, U.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Moulin, Emmanuel
A1 - Naumann, C. L.
A1 - Naumann-Godo, M.
A1 - de Naurois, M.
A1 - Nedbal, D.
A1 - Nguyen, N.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perez, J.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Raue, M.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Ripken, J.
A1 - Rob, L.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sheidaei, F.
A1 - Skilton, J. L.
A1 - Sol, H.
A1 - Spengler, G.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Szostek, A.
A1 - Tavernet, J. -P.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, C.
A1 - Vasileiadis, G.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorobiov, S.
A1 - Vorster, M.
A1 - Wagner, S. J.
A1 - Ward, M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Wouters, D.
A1 - Zacharias, M.
A1 - Zajczyk, A.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. S.
T1 - HESS discovery of VHE gamma-rays from the quasar PKS 1510-089
JF - Astronomy and astrophysics : an international weekly journal
N2 - The quasar PKS 1510-089 (z = 0.361) was observed with the H.E.S.S. array of imaging atmospheric Cherenkov telescopes during high states in the optical and GeV bands, to search for very high energy (VHE, defined as E >= 0.1 TeV) emission. VHE gamma-rays were detected with a statistical significance of 9.2 standard deviations in 15.8 h of H. E. S. S. data taken during March and April 2009. A VHE integral flux of I(0.15 TeV < E < 1.0TeV) = (1.0 +/- 0.2(stat) +/- 0.2(sys)) x 10(-11) cm(-2) s(-1) is measured. The best-fit power law to the VHE data has a photon index of G = 5.4 +/- 0.7(stat) +/- 0.3(sys). The GeV and optical light curves show pronounced variability during the period of H.E.S.S. observations. However, there is insufficient evidence to claim statistically significant variability in the VHE data. Because of its relatively high redshift, the VHE flux from PKS 1510-089 should suffer considerable attenuation in the intergalactic space due to the extragalactic background light (EBL). Hence, the measured gamma-ray spectrum is used to derive upper limits on the opacity due to EBL, which are found to be comparable with the previously derived limits from relatively-nearby BL Lac objects. Unlike typical VHE-detected blazars where the broadband spectrum is dominated by nonthermal radiation at all wavelengths, the quasar PKS 1510-089 has a bright thermal component in the optical to UV frequency band. Among all VHE detected blazars, PKS 1510-089 has the most luminous broad line region. The detection of VHE emission from this quasar indicates a low level of gamma - gamma absorption on the internal optical to UV photon field.
KW - gamma rays: galaxies
KW - quasars: individual: PKS 1510-089
KW - infrared: diffuse background
Y1 - 2013
U6 - https://doi.org/10.1051/0004-6361/201321135
SN - 0004-6361
VL - 554
IS - 6
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Acero, F.
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Anton, Gisela
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Bissaldi, E.
A1 - Biteau, Jonathan
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Brucker, J.
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chadwick, Paula M.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Cheesebrough, A.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Dalton, M.
A1 - Daniel, M. K.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Dickinson, H. J.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Drury, L. O'C.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, M.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Gast, H.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Goering, D.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Haeffner, S.
A1 - Hague, J. D.
A1 - Hahn, J.
A1 - Harris, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, Markus
A1 - Horns, D.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kneiske, T.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J-P.
A1 - Lennarz, D.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C-C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - McComb, T. J. L.
A1 - Medina, M. C.
A1 - Mehault, J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Naumann, C. L.
A1 - de Naurois, M.
A1 - Nedbal, D.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Oakes, L.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perez, J.
A1 - Petrucci, P-O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Raue, M.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Rob, L.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sol, H.
A1 - Spengler, G.
A1 - Spiess, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Szostek, A.
A1 - Tavernet, J-P.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, C.
A1 - Vasileiadis, G.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorster, M.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Ward, M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Zacharias, M.
A1 - Zajczyk, A.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H-S.
T1 - Constraints on axionlike particles with HESS from the irregularity of the PKS 2155-304 energy spectrum
JF - Physical review : D, Particles, fields, gravitation, and cosmology
N2 - Axionlike particles (ALPs) are hypothetical light (sub-eV) bosons predicted in some extensions of the Standard Model of particle physics. In astrophysical environments comprising high-energy gamma rays and turbulent magnetic fields, the existence of ALPs can modify the energy spectrum of the gamma rays for a sufficiently large coupling between ALPs and photons. This modification would take the form of an irregular behavior of the energy spectrum in a limited energy range. Data from the H. E. S. S. observations of the distant BL Lac object PKS 2155 - 304 (z = 0.116) are used to derive upper limits at the 95% C. L. on the strength of the ALP coupling to photons, g(gamma a) < 2.1 x 10(-11) GeV-1 for an ALP mass between 15 and 60 neV. The results depend on assumptions on the magnetic field around the source, which are chosen conservatively. The derived constraints apply to both light pseudoscalar and scalar bosons that couple to the electromagnetic field.
Y1 - 2013
U6 - https://doi.org/10.1103/PhysRevD.88.102003
SN - 1550-7998
SN - 1550-2368
VL - 88
IS - 10
PB - American Physical Society
CY - College Park
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Angüner, Ekrem Oǧuzhan
A1 - Arakawa, M.
A1 - Arcaro, C.
A1 - Armand, C.
A1 - Backes, M.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Berge, D.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Bottcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bonnefoy, S.
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Buechele, M.
A1 - Bulik, T.
A1 - Bylund, T.
A1 - Capasso, M.
A1 - Caroff, S.
A1 - Carosi, A.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chand, T.
A1 - Chandra, S.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Colafrancesco, S.
A1 - Condon, B.
A1 - Davids, I. D.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Dmytriiev, A.
A1 - Donath, A.
A1 - Doroshenko, V
A1 - Dyks, J.
A1 - Egberts, Kathrin
A1 - Emery, G.
A1 - Ernenwein, J-P
A1 - Eschbach, S.
A1 - Feijen, K.
A1 - Fegan, S.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gallant, Y. A.
A1 - Gate, F.
A1 - Giavitto, G.
A1 - Glawion, D.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M-H
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holch, Tim Lukas
A1 - Holler, M.
A1 - Horns, D.
A1 - Huber, D.
A1 - Iwasaki, H.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jouvin, L.
A1 - Jung-Richardt, I
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - King, J.
A1 - Klepser, S.
A1 - Kluzniak, W.
A1 - Komin, Nu
A1 - Kosack, K.
A1 - Kostunin, D.
A1 - Kraus, M.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J-P
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lopez-Coto, R.
A1 - Lypova, I
A1 - Malyshev, D.
A1 - Marandon, V
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marti-Devesa, G.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Meintjes, P. J.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Moore, C.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Ndiyavala, H.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Ostrowski, M.
A1 - Oya, I
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Perennes, C.
A1 - Petrucci, P-O
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poireau, V
A1 - Noel, A. Priyana
A1 - Prokhorov, D. A.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Rauth, R.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - Rieger, F.
A1 - Rinchiuso, L.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Ruiz-Velasco, E.
A1 - Sahakian, V
A1 - Saito, S.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schutte, H.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Senniappan, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I
A1 - Shiningayamwe, K.
A1 - Simoni, R.
A1 - Sinha, A.
A1 - Sol, H.
A1 - Specovius, A.
A1 - Spir-Jacob, M.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Steppa, Constantin Beverly
A1 - Takahashi, T.
A1 - Tavernet, J-P
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, Luigi
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsirou, M.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Yang, R.
A1 - Yoneda, H.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Ziegler, A.
A1 - Zorn, J.
A1 - Zywucka, N.
T1 - H.E.S.S. and Suzaku observations of the Vela X pulsar wind nebula
JF - Astronomy and astrophysics : an international weekly journal
N2 - Context. Pulsar wind nebulae (PWNe) represent the most prominent population of Galactic very-high-energy gamma-ray sources and are thought to be an efficient source of leptonic cosmic rays. Vela X is a nearby middle-aged PWN, which shows bright X-ray and TeV gamma-ray emission towards an elongated structure called the cocoon. Aims. Since TeV emission is likely inverse-Compton emission of electrons, predominantly from interactions with the cosmic microwave background, while X-ray emission is synchrotron radiation of the same electrons, we aim to derive the properties of the relativistic particles and of magnetic fields with minimal modelling. Methods. We used data from the Suzaku XIS to derive the spectra from three compact regions in Vela X covering distances from 0.3 to 4 pc from the pulsar along the cocoon. We obtained gamma-ray spectra of the same regions from H.E.S.S. observations and fitted a radiative model to the multi-wavelength spectra. Results. The TeV electron spectra and magnetic field strengths are consistent within the uncertainties for the three regions, with energy densities of the order 10(-12) erg cm(-3). The data indicate the presence of a cutoff in the electron spectrum at energies of similar to 100 TeV and a magnetic field strength of similar to 6 mu G. Constraints on the presence of turbulent magnetic fields are weak. Conclusions. The pressure of TeV electrons and magnetic fields in the cocoon is dynamically negligible, requiring the presence of another dominant pressure component to balance the pulsar wind at the termination shock. Sub-TeV electrons cannot completely account for the missing pressure, which may be provided either by relativistic ions or from mixing of the ejecta with the pulsar wind. The electron spectra are consistent with expectations from transport scenarios dominated either by advection via the reverse shock or by diffusion, but for the latter the role of radiative losses near the termination shock needs to be further investigated in the light of the measured cutoff energies. Constraints on turbulent magnetic fields and the shape of the electron cutoff can be improved by spectral measurements in the energy range greater than or similar to 10 keV.
KW - stars: winds, outflows
KW - gamma rays: stars
KW - radiation mechanisms: non-thermal
KW - acceleration of particles
KW - pulsars: individual: PSR B0833-45
Y1 - 2019
U6 - https://doi.org/10.1051/0004-6361/201935458
SN - 1432-0746
VL - 627
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Anguener, E. O.
A1 - Arakawa, M.
A1 - Arcaro, C.
A1 - Armand, C.
A1 - Ashkar, H.
A1 - Backes, M.
A1 - Martins, V. Barbosa
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Berge, D.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Boettcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bonnefoy, S.
A1 - Bregeon, J.
A1 - Breuhaus, M.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Buechele, M.
A1 - Bulik, T.
A1 - Bylund, T.
A1 - Capasso, M.
A1 - Caroff, S.
A1 - Carosi, A.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chand, T.
A1 - Chandra, S.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Colafrancesco, S.
A1 - Curylo, M.
A1 - Davids, I. D.
A1 - Deil, C.
A1 - Devin, J.
A1 - de Wilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Dmytriiev, A.
A1 - Donath, A.
A1 - Doroshenko, V
A1 - Dyks, J.
A1 - Egberts, Kathrin
A1 - Emery, G.
A1 - Ernenwein, J-p
A1 - Eschbach, S.
A1 - Feijen, K.
A1 - Fegan, S.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gallant, Y. A.
A1 - Gate, F.
A1 - Giavitto, G.
A1 - Glawion, D.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M-H
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holch, Tim Lukas
A1 - Holler, M.
A1 - Horns, D.
A1 - Huber, D.
A1 - Iwasaki, H.
A1 - Jamrozy, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jung-Richardt, I
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - King, J.
A1 - Klepser, S.
A1 - Kluzniak, W.
A1 - Komin, Nu
A1 - Kosack, K.
A1 - Kostunin, D.
A1 - Kraus, M.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J-P
A1 - Leser, Eva
A1 - Levy, C.
A1 - Lohse, T.
A1 - Lopez-Coto, R.
A1 - Lypova, I
A1 - Mackey, J.
A1 - Majumdar, J.
A1 - Malyshev, D.
A1 - Marandon, V
A1 - Marcowith, Alexandre
A1 - Mares, A.
A1 - Mariaud, C.
A1 - Marti-Devesa, G.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Meintjes, P. J.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Muller, J.
A1 - Moore, C.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Ndiyavala, H.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Ostrowski, M.
A1 - Oya, I
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Perennes, C.
A1 - Petrucci, P-O
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poireau, V
A1 - Noel, A. Priyana
A1 - Prokhorov, D. A.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Rauth, R.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Remy, Q.
A1 - Renaud, M.
A1 - Rieger, F.
A1 - Rinchiuso, L.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Ruiz-Velasco, E.
A1 - Sahakian, V
A1 - Saito, S.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schutte, H.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Senniappan, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shiningayamwe, K.
A1 - Simoni, R.
A1 - Sinha, A.
A1 - Sol, H.
A1 - Specovius, A.
A1 - Spir-Jacob, M.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Steppa, Constantin Beverly
A1 - Takahashi, T.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsirou, M.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Yang, R.
A1 - Yoneda, H.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Ziegler, A.
A1 - Zorn, J.
A1 - Zywucka, N.
A1 - Maxted, N.
T1 - Upper limits on very-high-energy gamma-ray emission from core-collapse supernovae observed with H.E.S.S.
JF - Astronomy and astrophysics : an international weekly journal
N2 - Young core-collapse supernovae with dense-wind progenitors may be able to accelerate cosmic-ray hadrons beyond the knee of the cosmic-ray spectrum, and this may result in measurable gamma-ray emission. We searched for gamma-ray emission from ten super- novae observed with the High Energy Stereoscopic System (H.E.S.S.) within a year of the supernova event. Nine supernovae were observed serendipitously in the H.E.S.S. data collected between December 2003 and December 2014, with exposure times ranging from 1.4 to 53 h. In addition we observed SN 2016adj as a target of opportunity in February 2016 for 13 h. No significant gamma-ray emission has been detected for any of the objects, and upper limits on the >1 TeV gamma-ray flux of the order of similar to 10(-13) cm(-)(2)s(-1) are established, corresponding to upper limits on the luminosities in the range similar to 2 x 10(39) to similar to 1 x 10(42) erg s(-1). These values are used to place model-dependent constraints on the mass-loss rates of the progenitor stars, implying upper limits between similar to 2 x 10(-5) and similar to 2 x 10(-3) M-circle dot yr(-1) under reasonable assumptions on the particle acceleration parameters.
KW - gamma rays: general
KW - supernovae: general
KW - cosmic rays
Y1 - 2019
U6 - https://doi.org/10.1051/0004-6361/201935242
SN - 1432-0746
VL - 626
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Angüner, Ekrem Oǧuzhan
A1 - Arakawa, M.
A1 - Arcaro, C.
A1 - Armand, C.
A1 - Arrieta, M.
A1 - Backes, M.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Bottcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bonnefoy, S.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Buchele, M.
A1 - Bulik, T.
A1 - Bylund, T.
A1 - Capasso, M.
A1 - Caroff, S.
A1 - Carosi, A.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chand, T.
A1 - Chandra, S.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Colafrancesco, S.
A1 - Condon, B.
A1 - Davids, I. D.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Dmytriiev, A.
A1 - Donath, A.
A1 - Doroshenko, V.
A1 - Dyks, J.
A1 - Egberts, Kathrin
A1 - Emery, G.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Fegan, S.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gallant, Y. A.
A1 - Gate, F.
A1 - Giavitto, G.
A1 - Glawion, D.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M. -H.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holch, Tim Lukas
A1 - Holler, M.
A1 - Horns, D.
A1 - Huber, D.
A1 - Iwasaki, H.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - King, J.
A1 - Klepser, S.
A1 - Kluzniak, W.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Kraus, M.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lefaucheur, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lopez-Coto, R.
A1 - Lorentz, M.
A1 - Lypova, I.
A1 - Malyshev, D.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marti-Devesa, G.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Meintjes, P. J.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Moore, C.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Ndiyavala, H.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poireau, V.
A1 - Noel, A. Priyana
A1 - Prokhorov, D. A.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Rauth, R.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - Rieger, F.
A1 - Rinchiuso, L.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Ruiz-Velasco, E.
A1 - Sahakian, V.
A1 - Saito, S.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schutte, H.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Senniappan, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Shiningayamwe, K.
A1 - Simoni, R.
A1 - Sinha, A.
A1 - Sol, H.
A1 - Specovius, A.
A1 - Spir-Jacob, M.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Steppa, Constantin Beverly
A1 - Takahashi, T.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsirou, M.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Yang, R.
A1 - Yoneda, H.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Ziegler, A.
A1 - Zorn, J.
A1 - Zywucka, N.
T1 - H.E.S.S. observations of the flaring gravitationally lensed galaxy PKS 1830-211
JF - Monthly notices of the Royal Astronomical Society
N2 - PKS 1830-211 is a known macrolensed quasar located at a redshift of z = 2.5. Its highenergy gamma-ray emission has been detected with the Fermi-Large Area Telescope (LAT) instrument and evidence for lensing was obtained by several authors from its high-energy data. Observations of PKS 1830-211 were taken with the High Energy Stereoscopic System (H.E.S.S.) array of Imaging Atmospheric Cherenkov Telescopes in 2014 August, following a flare alert by the Fermi-LAT Collaboration. The H.E.S.S observations were aimed at detecting a gamma-ray flare delayed by 20-27 d from the alert flare, as expected from observations at other wavelengths. More than 12 h of good-quality data were taken with an analysis threshold of similar to 67 GeV. The significance of a potential signal is computed as a function of the date and the average significance over the whole period. Data are compared to simultaneous observations by Fermi-LAT. No photon excess or significant signal is detected. An upper limit on PKS 1830-211 flux above 67 GeV is computed and compared to the extrapolation of the Fermi-LAT flare spectrum.
KW - gravitational lensing: strong
KW - diffuse radiation
KW - gamma-rays: galaxies
Y1 - 2019
U6 - https://doi.org/10.1093/mnras/stz1031
SN - 0035-8711
SN - 1365-2966
VL - 486
IS - 3
SP - 3886
EP - 3891
PB - Oxford Univ. Press
CY - Oxford
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Backes, Michael
A1 - Balzer, Arnim
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Berge, David
A1 - Bernhard, Sabrina
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Blackwell, R.
A1 - Boettcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, Johan
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bryan, Mark
A1 - Bulik, Tomasz
A1 - Carr, John
A1 - Casanova, Sabrina
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Chen, Andrew
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Djannati-Ata, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J-P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Goyal, A.
A1 - Grondin, M-H.
A1 - Grudzinska, M.
A1 - Hadasch, D.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J-P.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C-C.
A1 - Lui, R.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Oettl, S.
A1 - Ohm, S.
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Petrucci, P-O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reichardt, I.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seyffert, A. S.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Tavernet, J-P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tuffs, R.
A1 - Valerius, K.
A1 - van der Walt, J.
A1 - van Eldik, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Zywucka, N.
T1 - Acceleration of petaelectronvolt protons in the Galactic Centre
JF - Nature : the international weekly journal of science
N2 - Galactic cosmic rays reach energies of at least a few petaelectronvolts (of the order of 1015 electronvolts). This implies that our Galaxy contains petaelectronvolt accelerators (‘PeVatrons’), but all proposed models of Galactic cosmic-ray accelerators encounter difficulties at exactly these energies. Dozens of Galactic accelerators capable of accelerating particles to energies of tens of teraelectronvolts (of the order of 1013 electronvolts) were inferred from recent γ-ray observations3. However, none of the currently known accelerators—not even the handful of shell-type supernova remnants commonly believed to supply most Galactic cosmic rays—has shown the characteristic tracers of petaelectronvolt particles, namely, power-law spectra of γ-rays extending without a cut-off or a spectral break to tens of teraelectronvolts4. Here we report deep γ-ray observations with arcminute angular resolution of the region surrounding the Galactic Centre, which show the expected tracer of the presence of petaelectronvolt protons within the central 10 parsecs of the Galaxy. We propose that the supermassive black hole Sagittarius A* is linked to this PeVatron. Sagittarius A* went through active phases in the past, as demonstrated by X-ray outbursts5and an outflow from the Galactic Centre6. Although its current rate of particle acceleration is not sufficient to provide a substantial contribution to Galactic cosmic rays, Sagittarius A* could have plausibly been more active over the last 106–107 years, and therefore should be considered as a viable alternative to supernova remnants as a source of petaelectronvolt Galactic cosmic rays.
Y1 - 2016
U6 - https://doi.org/10.1038/nature17147
SN - 0028-0836
SN - 1476-4687
VL - 531
SP - 476
EP - +
PB - Nature Publ. Group
CY - London
ER -
TY - GEN
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Anton, Gisela
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Bissaldi, E.
A1 - Biteau, Jonathan
A1 - Boettcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Brucker, J.
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chadwick, Paula M.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Cheesebrough, A.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Dalton, M.
A1 - Daniel, M. K.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Dickinson, H. J.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, M.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Harris, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, M.
A1 - Horns, D.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kneiske, T.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lennarz, D.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, Michael
A1 - McComb, T. J. L.
A1 - Mehault, J.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Naumann, C. L.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Oakes, L.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perez, J.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Raue, M.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Rob, L.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sol, H.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Szostek, A.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorster, M.
A1 - Vuillaume, T.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Ward, M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Zabalza, V.
A1 - Zacharias, M.
A1 - Zajczyk, A.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. -S.
T1 - HESS J1640-465 - an exceptionally luminous TeV gamma-ray supernova remnant (vol 439, pg 2828, 2014)
T2 - Monthly notices of the Royal Astronomical Society
KW - errata, addenda
KW - radiation mechanisms: non-thermal
KW - ISM: individual objects: G338.3-0.0
KW - ISM: supernova remnants
Y1 - 2014
U6 - https://doi.org/10.1093/mnras/stu826
SN - 0035-8711
SN - 1365-2966
VL - 441
IS - 4
SP - 3640
EP - 3642
PB - Oxford Univ. Press
CY - Oxford
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Acero, F.
A1 - Aharonian, Felix A.
A1 - Akhperjanian, A. G.
A1 - Anton, Gisela
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Biteau, Jonathan
A1 - Bochow, A.
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Brucker, J.
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chadwick, Paula M.
A1 - Chaves, Ryan C. G.
A1 - Cheesebrough, A.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Dalton, M.
A1 - Daniel, M. K.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Dickinson, H. J.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Drury, L. O'C.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Fallon, L.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fussling, Matthias
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Gast, H.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Glueck, B.
A1 - Goering, D.
A1 - Grondin, M. -H.
A1 - Haeffner, S.
A1 - Hague, J. D.
A1 - Hahn, J.
A1 - Hampf, D.
A1 - Harris, J.
A1 - Heinz, S.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, M.
A1 - Horns, D.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Jung, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kneiske, T.
A1 - Komin, Nu
A1 - Kosack, K.
A1 - Kossakowski, R.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Lennarz, D.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Masbou, J.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - McComb, T. J. L.
A1 - Medina, M. C.
A1 - Mehault, J.
A1 - Menzler, U.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Moulin, Emmanuel
A1 - Naumann, C. L.
A1 - Naumann-Godo, M.
A1 - de Naurois, M.
A1 - Nedbal, D.
A1 - Nekrassov, D.
A1 - Nguyen, N.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Ohm, S.
A1 - Awilhelmi, E. de Ona
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Arribas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perez, J.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raue, M.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Ripken, J.
A1 - Rob, L.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sheidaei, F.
A1 - Skilton, J. L.
A1 - Sol, H.
A1 - Spengler, G.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Szostek, A.
A1 - Tavernet, J. -P.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, C.
A1 - Vasileiadis, G.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorobiov, S.
A1 - Vorster, M.
A1 - Wagner, S. J.
A1 - Ward, M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Wouters, D.
A1 - Zacharias, M.
A1 - Zajczyk, A.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. -S.
T1 - Search for Photon-Linelike Signatures from Dark Matter Annihilations with H.E.S.S.
JF - Physical review letters
N2 - Gamma-ray line signatures can be expected in the very-high-energy (E-gamma > 100 GeV) domain due to self-annihilation or decay of dark matter (DM) particles in space. Such a signal would be readily distinguishable from astrophysical gamma-ray sources that in most cases produce continuous spectra that span over several orders of magnitude in energy. Using data collected with the H. E. S. S. gamma-ray instrument, upper limits on linelike emission are obtained in the energy range between similar to 500 GeV and similar to 25 TeV for the central part of the Milky Way halo and for extragalactic observations, complementing recent limits obtained with the Fermi-LAT instrument at lower energies. No statistically significant signal could be found. For monochromatic gamma-ray line emission, flux limits of (2 x 10(-7)-2 x 10(-5)) m(-2)s(-1)sr(-1) and (1 x 10(-8)- 2 x 10(-6)) m(-2)s(-1)sr(-1) are obtained for the central part of the Milky Way halo and extragalactic observations, respectively. For a DM particle mass of 1 TeV, limits on the velocity- averaged DM annihilation cross section (chi chi ->gamma gamma) reach similar to 10(-27)cm(3)s(-1), based on the Einasto parametrization of the Galactic DM halo density profile. DOI: 10.1103/PhysRevLett.110.041301
Y1 - 2013
U6 - https://doi.org/10.1103/PhysRevLett.110.041301
SN - 0031-9007
VL - 110
IS - 4
PB - American Physical Society
CY - College Park
ER -
TY - JOUR
A1 - De Angelis, A.
A1 - Tatischeff, V.
A1 - Grenier, I. A.
A1 - McEnery, J.
A1 - Mallamaci, Manuela
A1 - Tavani, M.
A1 - Oberlack, U.
A1 - Hanlon, L.
A1 - Walter, R.
A1 - Argan, A.
A1 - Von Ballmoos, P.
A1 - Bulgarelli, A.
A1 - Bykov, A.
A1 - Hernanz, M.
A1 - Kanbach, G.
A1 - Kuvvetli, I.
A1 - Pearce, M.
A1 - Zdziarski, A.
A1 - Conrad, J.
A1 - Ghisellini, G.
A1 - Harding, A.
A1 - Isern, J.
A1 - Leising, M.
A1 - Longo, F.
A1 - Madejski, G.
A1 - Martinez, M.
A1 - Mazziotta, Mario Nicola
A1 - Paredes, J. M.
A1 - Pohl, Martin
A1 - Rando, R.
A1 - Razzano, M.
A1 - Aboudan, A.
A1 - Ackermann, M.
A1 - Addazi, A.
A1 - Ajello, M.
A1 - Albertus, C.
A1 - Alvarez, J. M.
A1 - Ambrosi, G.
A1 - Anton, S.
A1 - Antonelli, L. A.
A1 - Babic, A.
A1 - Baibussinov, B.
A1 - Balbom, M.
A1 - Baldini, L.
A1 - Balman, S.
A1 - Bambi, C.
A1 - Barres de Almeida, U.
A1 - Barrio, J. A.
A1 - Bartels, R.
A1 - Bastieri, D.
A1 - Bednarek, W.
A1 - Bernard, D.
A1 - Bernardini, E.
A1 - Bernasconi, T.
A1 - Bertucci, B.
A1 - Biland, A.
A1 - Bissaldi, E.
A1 - Boettcher, M.
A1 - Bonvicini, V.
A1 - Bosch-Ramon, V.
A1 - Bottacini, E.
A1 - Bozhilov, V.
A1 - Bretz, T.
A1 - Branchesi, M.
A1 - Brdar, V.
A1 - Bringmann, T.
A1 - Brogna, A.
A1 - Jorgensen, C. Budtz
A1 - Busetto, G.
A1 - Buson, S.
A1 - Busso, M.
A1 - Caccianiga, A.
A1 - Camera, S.
A1 - Campana, R.
A1 - Caraveo, P.
A1 - Cardillo, M.
A1 - Carlson, P.
A1 - Celestin, S.
A1 - Cermeno, M.
A1 - Chen, A.
A1 - Cheung, C. C.
A1 - Churazov, E.
A1 - Ciprini, S.
A1 - Coc, A.
A1 - Colafrancesco, S.
A1 - Coleiro, A.
A1 - Collmar, W.
A1 - Coppi, P.
A1 - Curado da Silva, R.
A1 - Cutini, S.
A1 - De Lotto, B.
A1 - de Martino, D.
A1 - De Rosa, A.
A1 - Del Santo, M.
A1 - Delgado, L.
A1 - Diehl, R.
A1 - Dietrich, S.
A1 - Dolgov, A. D.
A1 - Dominguez, A.
A1 - Prester, D. Dominis
A1 - Donnarumma, I.
A1 - Dorner, D.
A1 - Doro, M.
A1 - Dutra, M.
A1 - Elsaesser, D.
A1 - Fabrizio, M.
A1 - Fernandez-Barral, A.
A1 - Fioretti, V.
A1 - Foffano, L.
A1 - Formato, V.
A1 - Fornengo, N.
A1 - Foschini, L.
A1 - Franceschini, A.
A1 - Franckowiak, A.
A1 - Funk, S.
A1 - Fuschino, F.
A1 - Gaggero, D.
A1 - Galanti, G.
A1 - Gargano, F.
A1 - Gasparrini, D.
A1 - Gehrz, R.
A1 - Giammaria, P.
A1 - Giglietto, N.
A1 - Giommi, P.
A1 - Giordano, F.
A1 - Giroletti, M.
A1 - Ghirlanda, G.
A1 - Godinovic, N.
A1 - Gouiffes, C.
A1 - Grove, J. E.
A1 - Hamadache, C.
A1 - Hartmann, D. H.
A1 - Hayashida, M.
A1 - Hryczuk, A.
A1 - Jean, P.
A1 - Johnson, T.
A1 - Jose, J.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kiener, J.
A1 - Knodlseder, J.
A1 - Kolem, M.
A1 - Kopp, J.
A1 - Kozhuharov, V.
A1 - Labanti, C.
A1 - Lalkovski, S.
A1 - Laurent, P.
A1 - Limousin, O.
A1 - Linares, M.
A1 - Lindfors, E.
A1 - Lindner, M.
A1 - Liu, J.
A1 - Lombardi, S.
A1 - Loparco, F.
A1 - Lopez-Coto, R.
A1 - Lopez Moya, M.
A1 - Lott, B.
A1 - Lubrano, P.
A1 - Malyshev, D.
A1 - Mankuzhiyil, N.
A1 - Mannheim, K.
A1 - Marcha, M. J.
A1 - Marciano, A.
A1 - Marcote, B.
A1 - Mariotti, M.
A1 - Marisaldi, M.
A1 - McBreen, S.
A1 - Mereghetti, S.
A1 - Merle, A.
A1 - Mignani, R.
A1 - Minervini, G.
A1 - Moiseev, A.
A1 - Morselli, A.
A1 - Moura, F.
A1 - Nakazawa, K.
A1 - Nava, L.
A1 - Nieto, D.
A1 - Orienti, M.
A1 - Orio, M.
A1 - Orlando, E.
A1 - Orleanski, P.
A1 - Paiano, S.
A1 - Paoletti, R.
A1 - Papitto, A.
A1 - Pasquato, M.
A1 - Patricelli, B.
A1 - Perez-Garcia, M. A.
A1 - Persic, M.
A1 - Piano, G.
A1 - Pichel, A.
A1 - Pimenta, M.
A1 - Pittori, C.
A1 - Porter, T.
A1 - Poutanen, J.
A1 - Prandini, E.
A1 - Prantzos, N.
A1 - Produit, N.
A1 - Profumo, S.
A1 - Queiroz, F. S.
A1 - Raino, S.
A1 - Raklev, A.
A1 - Regis, M.
A1 - Reichardt, I.
A1 - Rephaeli, Y.
A1 - Rico, J.
A1 - Rodejohann, W.
A1 - Fernandez, G. Rodriguez
A1 - Roncadelli, M.
A1 - Roso, L.
A1 - Rovero, A.
A1 - Ruffini, R.
A1 - Sala, G.
A1 - Sanchez-Conde, M. A.
A1 - Santangelo, Andrea
A1 - Parkinson, P. Saz
A1 - Sbarrato, T.
A1 - Shearer, A.
A1 - Shellard, R.
A1 - Short, K.
A1 - Siegert, T.
A1 - Siqueira, C.
A1 - Spinelli, P.
A1 - Stamerra, A.
A1 - Starrfield, S.
A1 - Strong, A.
A1 - Strumke, I.
A1 - Tavecchio, F.
A1 - Taverna, R.
A1 - Terzic, T.
A1 - Thompson, D. J.
A1 - Tibolla, O.
A1 - Torres, D. F.
A1 - Turolla, R.
A1 - Ulyanov, A.
A1 - Ursi, A.
A1 - Vacchi, A.
A1 - Van den Abeele, J.
A1 - Vankova-Kirilovai, G.
A1 - Venter, C.
A1 - Verrecchia, F.
A1 - Vincent, P.
A1 - Wang, X.
A1 - Weniger, C.
A1 - Wu, X.
A1 - Zaharijas, G.
A1 - Zampieri, L.
A1 - Zane, S.
A1 - Zimmer, S.
A1 - Zoglauer, A.
T1 - Science with e-ASTROGAM A space mission for MeV-GeV gamma-ray astrophysics
JF - Journal of High Energy Astrophysics
Y1 - 2018
U6 - https://doi.org/10.1016/j.jheap.2018.07.001
SN - 2214-4048
SN - 2214-4056
VL - 19
SP - 1
EP - 106
PB - Elsevier
CY - Amsterdam
ER -
TY - JOUR
A1 - Cheng, Xin
A1 - Zhang, Jie
A1 - Kliem, Bernhard
A1 - Török, Tibor
A1 - Xing, Chen
A1 - Zhou, Zhenjun
A1 - Inhester, Bernd
A1 - Ding, Mingde
T1 - Initiation and early kinematic evolution of solar eruptions
JF - The Astrophysical Journal
N2 - We investigate the initiation and early evolution of 12 solar eruptions, including six active-region hot channel and six quiescent filament eruptions, which were well observed by the Solar Dynamics Observatory, as well as by the Solar Terrestrial Relations Observatory for the latter. The sample includes one failed eruption and 11 coronal mass ejections, with velocities ranging from 493 to 2140 km s(-1). A detailed analysis of the eruption kinematics yields the following main results. (1) The early evolution of all events consists of a slow-rise phase followed by a main-acceleration phase, the height-time profiles of which differ markedly and can be best fit, respectively, by a linear and an exponential function. This indicates that different physical processes dominate in these phases, which is at variance with models that involve a single process. (2) The kinematic evolution of the eruptions tends to be synchronized with the flare light curve in both phases. The synchronization is often but not always close. A delayed onset of the impulsive flare phase is found in the majority of the filament eruptions (five out of six). This delay and its trend to be larger for slower eruptions favor ideal MHD instability models. (3) The average decay index at the onset heights of the main acceleration is close to the threshold of the torus instability for both groups of events (although, it is based on a tentative coronal field model for the hot channels), suggesting that this instability initiates and possibly drives the main acceleration.
KW - solar coronal mass ejections
KW - stellar coronal mass ejections
KW - solar storm
Y1 - 2020
U6 - https://doi.org/10.3847/1538-4357/ab886a
SN - 1055-6796
SN - 1476-3540
VL - 894
IS - 2
SP - 1
EP - 20
PB - Cambridge Scientific Publishers
CY - Cambridge
ER -
TY - THES
A1 - Ketzer, Laura
T1 - The impact of stellar activity evolution on atmospheric mass loss of young exoplanets
T1 - Der Einfluss der stellaren Aktivitätsentwicklung auf den atmosphärischen Massenverlust von jungen Exoplaneten
N2 - The increasing number of known exoplanets raises questions about their demographics and the mechanisms that shape planets into how we observe them today. Young planets in close-in orbits are exposed to harsh environments due to the host star being magnetically highly active, which results in high X-ray and extreme UV fluxes impinging on the planet. Prolonged exposure to this intense photoionizing radiation can cause planetary atmospheres to heat up, expand and escape into space via a hydrodynamic escape process known as photoevaporation. For super-Earth and sub-Neptune-type planets, this can even lead to the complete erosion of their primordial gaseous atmospheres. A factor of interest for this particular mass-loss process is the activity evolution of the host star. Stellar rotation, which drives the dynamo and with it the magnetic activity of a star, changes significantly over the stellar lifetime. This strongly affects the amount of high-energy radiation received by a planet as stars age. At a young age, planets still host warm and extended envelopes, making them particularly susceptible to atmospheric evaporation. Especially in the first gigayear, when X-ray and UV levels can be 100 - 10,000 times higher than for the present-day sun, the characteristics of the host star and the detailed evolution of its high-energy emission are of importance.
In this thesis, I study the impact of stellar activity evolution on the high-energy-induced atmospheric mass loss of young exoplanets. The PLATYPOS code was developed as part of this thesis to calculate photoevaporative mass-loss rates over time. The code, which couples parameterized planetary mass-radius relations with an analytical hydrodynamic escape model, was used, together with Chandra and eROSITA X-ray observations, to investigate the future mass loss of the two young multiplanet systems V1298 Tau and K2-198. Further, in a numerical ensemble study, the effect of a realistic spread of activity tracks on the small-planet radius gap was investigated for the first time. The works in this thesis show that for individual systems, in particular if planetary masses are unconstrained, the difference between a young host star following a low-activity track vs. a high-activity one can have major implications: the exact shape of the activity evolution can determine whether a planet can hold on to some of its atmosphere, or completely loses its envelope, leaving only the bare rocky core behind. For an ensemble of simulated planets, an observationally-motivated distribution of activity tracks does not substantially change the final radius distribution at ages of several gigayears. My simulations indicate that the overall shape and slope of the resulting small-planet radius gap is not significantly affected by the spread in stellar activity tracks. However, it can account for a certain scattering or fuzziness observed in and around the radius gap of the observed exoplanet population.
N2 - Die steigende Anzahl bekannter Exoplaneten wirft Fragen zu ihrer Demografie und den Mechanismen auf, die Planeten in ihre heutige beobachtete Form bringen. Junge Planeten, die sehr nah um ihren Wirtsstern kreisen, sind extremen Umgebungen ausgesetzt, da der Stern eine hohe magnetische Aktivität aufweist. Das führt wiederum dazu, dass der Planet einer enormen Röntgen- und Extrem-UV-Strahlung ausgesetzt ist. Ist der Planet über einen längeren Zeitraum dieser intensiven photoionisierenden Strahlung ausgesetzt, kann dies dazu führen, dass Planetenatmosphären sich aufheizen, ausdehnen und durch einen hydrodynamischen Entweichungsprozess namens Photoevaporation ins All entweichen, sozusagen verdampfen. Bei Planeten, in der Größenordnung von Super-Erden und Sub-Neptunen, kann dies sogar zur vollständigen Erosion ihrer Ur-Atmosphären führen. Ein interessanter Faktor, der für diesen Massenverlustprozess eine Rolle spielt, ist die Aktivitätsentwicklung des Wirtssterns. Die Rotation eines Sterns, die den Dynamo und damit die magnetische Aktivität antreibt, ändert sich im Laufe der Lebensdauer eines Sterns erheblich. Dies hat einen starken Einfluss auf die Menge der hochenergetischen Strahlung, den ein Planet mit zunehmendem Alter des Sterns empfängt. In jungen Jahren besitzen Planeten noch warme und ausgedehnte Hüllen, was sie besonders anfällig für atmosphärische Verdunstung macht. Insbesondere in den ersten Gigajahren, wenn die Röntgen- und UV-Strahlung 100 - 10,000 Mal höher sein kann als bei der heutigen Sonne, sind die Eigenschaften des Wirtssterns und die detaillierte Entwicklung seiner hochenergetischen Emission von Bedeutung.
In dieser Arbeit untersuche ich die Auswirkungen der Entwicklung der stellaren Aktivität auf den durch hochenergetische Strahlung verursachten atmosphärischen Massenverlust junger Exoplaneten. Der PLATYPOS-Code wurde im Rahmen dieser Arbeit entwickelt, um die photoevaporativen Massenverlustraten für verschiedene stellare Alter zu berechnen. Der Code verknüpft parametrisierte Planetenmasse-Radius-Beziehungen mit einem analytischen Modell für den hydrodynamischen Massenverlust. Er wurde zusammen mit Chandra- und eROSITA-Röntgenbeobachtungen dazu verwendet, den zukünftigen Massenverlust der beiden jungen Mehrplanetensysteme V1298 Tau und K2-198 zu untersuchen. Darüber hinaus wurde in einer numerischen Ensemblestudie erstmals der Effekt einer realistischen Verteilung von stellaren Aktivitäts-Tracks auf das sogenannte Radius-Tal bei kleinen Planeten untersucht. Die Arbeiten in dieser Dissertation zeigen, dass für einzelne Systeme, insbesondere wenn die Planetenmassen unbestimmt sind, der Unterschied zwischen einem jungen Wirtsstern, der einem Track mit niedriger Aktivität gegenüber einem solchen mit hoher Aktivität folgt, gravierende Auswirkungen haben kann: Die genaue Form der Aktivitätsentwicklung kann darüber entscheiden, ob ein Planet einen Teil seiner Atmosphäre behält oder seine Hülle vollständig verliert und nur den nackten Gesteinskern behält. Für ein Ensemble von simulierten Planeten ändert eine durch Beobachtungen motivierte Verteilung von Aktivitäts-Tracks die endgültige Radiusverteilung der Planeten nach mehreren Gigajahren nicht wesentlich. Meine Simulationen deuten darauf hin, dass die Form und Steigung des sich ergebenden Radius-Tals bei Kleinplaneten nicht wesentlich von der Streuung der stellaren Aktivitäts-Tracks beeinflusst wird. Eine gewisse Streuung oder Unschärfe im Radius-Tal der beobachteten Exoplanetenpopulation kann damit allerdings durchaus erklärt werden.
KW - Exoplaneten
KW - star-planet interaction
KW - stellar physics
KW - exoplanets
KW - exoplanet atmospheres
KW - Sternphysik
KW - Stern-Planeten-Wechselwirkung
KW - Exoplanetenatmosphären
Y1 - 2024
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-626819
ER -
TY - JOUR
A1 - Herzog, Marc
A1 - Reppert, Alexander von
A1 - Pudell, Jan-Etienne
A1 - Henkel, Carsten
A1 - Kronseder, Matthias
A1 - Back, Christian H.
A1 - Maznev, Alexei A.
A1 - Bargheer, Matias
T1 - Phonon-dominated energy transport in purely metallic heterostructures
JF - Advanced functional materials
N2 - Ultrafast X-ray diffraction is used to quantify the transport of energy in laser-excited nanoscale gold-nickel (Au-Ni) bilayers.
Electron transport and efficient electron-phonon coupling in Ni convert the laser-deposited energy in the conduction electrons within a few picoseconds into a strong non-equilibrium between hot Ni and cold Au phonons at the bilayer interface.
Modeling of the subsequent equilibration dynamics within various two-temperature models confirms that for ultrathin Au films, the thermal transport is dominated by phonons instead of conduction electrons because of the weak electron-phonon coupling in Au.
KW - heterostructures
KW - nanoscale energy transports
KW - non-equilibrium
KW - thermal
KW - transports
KW - ultrafast phenomena
Y1 - 2022
U6 - https://doi.org/10.1002/adfm.202206179
SN - 1616-301X
SN - 1616-3028
VL - 32
IS - 41
PB - Wiley-VCH
CY - Weinheim
ER -
TY - JOUR
A1 - Herbst, Konstantin
A1 - Baalmann, Lennart R.
A1 - Bykov, Andrei
A1 - Engelbrecht, N. Eugene
A1 - Ferreira, Stefan E. S.
A1 - Izmodenov, Vladislav V.
A1 - Korolkov, Sergey D.
A1 - Levenfish, Ksenia P.
A1 - Linsky, Jeffrey L.
A1 - Meyer, Dominique M. -A.
A1 - Scherer, Klaus
A1 - Strauss, R. Du Toit
T1 - Astrospheres of planet-hosting cool stars and beyond when modeling meets observations
JF - Space science reviews
N2 - Thanks to dedicated long-term missions like Voyager and GOES over the past 50 years, much insight has been gained on the activity of our Sun, the solar wind, its interaction with the interstellar medium, and, thus, about the formation, the evolution, and the structure of the heliosphere. Additionally, with the help of multi-wavelength observations by the Hubble Space Telescope, Kepler, and TESS, we not only were able to detect a variety of extrasolar planets and exomoons but also to study the characteristics of their host stars, and thus became aware that other stars drive bow shocks and astrospheres. Although features like, e.g., stellar winds, could not be measured directly, over the past years several techniques have been developed allowing us to indirectly derive properties like stellar mass-loss rates and stellar wind speeds, information that can be used as direct input to existing astrospheric modeling codes. In this review, the astrospheric modeling efforts of various stars will be presented. Starting with the heliosphere as a benchmark of astrospheric studies, investigating the paleo-heliospheric changes and the Balmer H alpha projections to 1 pc, we investigate the surroundings of cool and hot stars, but also of more exotic objects like neutron stars. While pulsar wind nebulae (PWNs) might be a source of high-energy galactic cosmic rays (GCRs), the astrospheric environments of cool and hot stars form a natural shield against GCRs. Their modulation within these astrospheres, and the possible impact of turbulence, are also addressed. This review shows that all of the presented modeling efforts are in excellent agreement with currently available observations.
KW - Magneto-hydrodynamic modeling
KW - Stochastic differential equations
KW - Galactic cosmic rays
KW - Heliosphere
KW - Astrosphere
Y1 - 2022
U6 - https://doi.org/10.1007/s11214-022-00894-3
SN - 0038-6308
SN - 1572-9672
VL - 218
IS - 4
PB - Springer Nature
CY - Dordrecht
ER -
TY - JOUR
A1 - Bojahr, Andre
A1 - Gohlke, Matthias
A1 - Leitenberger, Wolfram
A1 - Pudell, Jan-Etienne
A1 - Reinhardt, Matthias
A1 - Reppert, Alexander von
A1 - Rössle, Matthias
A1 - Sander, Mathias
A1 - Gaal, Peter
A1 - Bargheer, Matias
T1 - Second Harmonic Generation of Nanoscale Phonon Wave Packets
JF - Physical review letters
N2 - Phonons are often regarded as delocalized quasiparticles with certain energy and momentum. The anharmonic interaction of phonons determines macroscopic properties of the solid, such as thermal expansion or thermal conductivity, and a detailed understanding becomes increasingly important for functional nanostructures. Although phonon-phonon scattering processes depicted in simple wave-vector diagrams are the basis of theories describing these macroscopic phenomena, experiments directly accessing these coupling channels are scarce. We synthesize monochromatic acoustic phonon wave packets with only a few cycles to introduce nonlinear phononics as the acoustic counterpart to nonlinear optics. Control of the wave vector, bandwidth, and consequently spatial extent of the phonon wave packets allows us to observe nonlinear phonon interaction, in particular, second harmonic generation, in real time by wave-vector-sensitive Brillouin scattering with x-rays and optical photons.
Y1 - 2015
U6 - https://doi.org/10.1103/PhysRevLett.115.195502
SN - 0031-9007
SN - 1079-7114
VL - 115
IS - 19
PB - American Physical Society
CY - College Park
ER -
TY - JOUR
A1 - Willig, Lisa
A1 - Reppert, Alexander von
A1 - Deb, Marwan
A1 - Ganss, F.
A1 - Hellwig, O.
A1 - Bargheer, Matias
T1 - Finite-size effects in ultrafast remagnetization dynamics of FePt
JF - Physical review : B, Condensed matter and materials physics
N2 - We investigate the ultrafast magnetization dynamics of FePt in the L1(0) phase after an optical heating pulse, as used in heat-assisted magnetic recording. We compare continuous and nano-granular thin films and emphasize the impact of the finite size on the remagnetization dynamics. The remagnetization speeds up significantly with increasing external magnetic field only for the continuous film, where domain-wall motion governs the dynamics. The ultrafast remagnetization dynamics in the continuous film are only dominated by heat transport in the regime of high magnetic fields, whereas the timescale required for cooling is prevalent in the granular film for all magnetic field strengths. These findings highlight the necessary conditions for studying the intrinsic heat transport properties in magnetic materials.
Y1 - 2019
U6 - https://doi.org/10.1103/PhysRevB.100.224408
SN - 2469-9950
SN - 2469-9969
VL - 100
IS - 22
PB - American Physical Society
CY - College Park
ER -
TY - JOUR
A1 - Koc, A.
A1 - Reinhardt, M.
A1 - Reppert, Alexander von
A1 - Rössle, Matthias
A1 - Leitenberger, Wolfram
A1 - Gleich, M.
A1 - Weinelt, M.
A1 - Zamponi, Flavio
A1 - Bargheer, Matias
T1 - Grueneisen-approach for the experimental determination of transient spin and phonon energies from ultrafast x-ray diffraction data: gadolinium
JF - Journal of physics : Condensed matter
N2 - We study gadolinium thin films as a model system for ferromagnets with negative thermal expansion. Ultrashort laser pulses heat up the electronic subsystem and we follow the transient strain via ultrafast x-ray diffraction. In terms of a simple Grueneisen approach, the strain is decomposed into two contributions proportional to the thermal energy of spin and phonon subsystems. Our analysis reveals that upon femtosecond laser excitation, phonons and spins can be driven out of thermal equilibrium for several nanoseconds.
KW - ultrafast
KW - x-ray diffraction
KW - magnetostriction
KW - nonequilibrium
KW - spin
KW - phonon
KW - rare earth
Y1 - 2017
U6 - https://doi.org/10.1088/1361-648X/aa7187
SN - 0953-8984
SN - 1361-648X
VL - 29
SP - 5884
EP - 5891
PB - IOP Publ. Ltd.
CY - Bristol
ER -
TY - JOUR
A1 - Cervantes Villa, Juan Sebastian
A1 - Shprits, Yuri Y.
A1 - Aseev, Nikita
A1 - Allison, Hayley J.
T1 - Quantifying the effects of EMIC wave scattering and magnetopause shadowing in the outer electron radiation belt by means of data assimilation
JF - Journal of geophysical research : Space physics
N2 - In this study we investigate two distinct loss mechanisms responsible for the rapid dropouts of radiation belt electrons by assimilating data from Van Allen Probes A and B and Geostationary Operational Environmental Satellites (GOES) 13 and 15 into a 3-D diffusion model. In particular, we examine the respective contribution of electromagnetic ion cyclotron (EMIC) wave scattering and magnetopause shadowing for values of the first adiabatic invariant mu ranging from 300 to 3,000 MeV G(-1). We inspect the innovation vector and perform a statistical analysis to quantitatively assess the effect of both processes as a function of various geomagnetic indices, solar wind parameters, and radial distance from the Earth. Our results are in agreement with previous studies that demonstrated the energy dependence of these two mechanisms. We show that EMIC wave scattering tends to dominate loss at lower L shells, and it may amount to between 10%/hr and 30%/hr of the maximum value of phase space density (PSD) over all L shells for fixed first and second adiabatic invariants. On the other hand, magnetopause shadowing is found to deplete electrons across all energies, mostly at higher L shells, resulting in loss from 50%/hr to 70%/hr of the maximum PSD. Nevertheless, during times of enhanced geomagnetic activity, both processes can operate beyond such location and encompass the entire outer radiation belt.
Y1 - 2020
U6 - https://doi.org/10.1029/2020JA028208
SN - 2169-9380
SN - 2169-9402
VL - 125
IS - 8
PB - American Geophysical Union
CY - Washington
ER -
TY - INPR
A1 - Acharya, B. S.
A1 - Actis, M.
A1 - Aghajani, T.
A1 - Agnetta, G.
A1 - Aguilar, J.
A1 - Aharonian, Felix A.
A1 - Ajello, M.
A1 - Akhperjanian, A. G.
A1 - Alcubierre, M.
A1 - Aleksic, J.
A1 - Alfaro, R.
A1 - Aliu, E.
A1 - Allafort, A. J.
A1 - Allan, D.
A1 - Allekotte, I.
A1 - Amato, E.
A1 - Anderson, J.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Antonelli, L. A.
A1 - Antoranz, P.
A1 - Aravantinos, A.
A1 - Arlen, T.
A1 - Armstrong, T.
A1 - Arnaldi, H.
A1 - Arrabito, L.
A1 - Asano, K.
A1 - Ashton, T.
A1 - Asorey, H. G.
A1 - Awane, Y.
A1 - Baba, H.
A1 - Babic, A.
A1 - Baby, N.
A1 - Baehr, J.
A1 - Bais, A.
A1 - Baixeras, C.
A1 - Bajtlik, S.
A1 - Balbo, M.
A1 - Balis, D.
A1 - Balkowski, C.
A1 - Bamba, A.
A1 - Bandiera, R.
A1 - Barber, A.
A1 - Barbier, C.
A1 - Barcelo, M.
A1 - Barnacka, Anna
A1 - Barnstedt, Jürgen
A1 - Barres de Almeida, U.
A1 - Barrio, J. A.
A1 - Basili, A.
A1 - Basso, S.
A1 - Bastieri, D.
A1 - Bauer, C.
A1 - Baushev, Anton N.
A1 - Becerra Gonzalez, J.
A1 - Becherini, Yvonne
A1 - Bechtol, K. C.
A1 - Tjus, J. Becker
A1 - Beckmann, Volker
A1 - Bednarek, W.
A1 - Behera, B.
A1 - Belluso, M.
A1 - Benbow, W.
A1 - Berdugo, J.
A1 - Berger, K.
A1 - Bernard, F.
A1 - Bernardino, T.
A1 - Bernlöhr, K.
A1 - Bhat, N.
A1 - Bhattacharyya, S.
A1 - Bigongiari, C.
A1 - Biland, A.
A1 - Billotta, S.
A1 - Bird, T.
A1 - Birsin, E.
A1 - Bissaldi, E.
A1 - Biteau, Jonathan
A1 - Bitossi, M.
A1 - Blake, S.
A1 - Blanch Bigas, O.
A1 - Blasi, P.
A1 - Bobkov, A. A.
A1 - Boccone, V.
A1 - Boettcher, Markus
A1 - Bogacz, L.
A1 - Bogart, J.
A1 - Bogdan, M.
A1 - Boisson, Catherine
A1 - Boix Gargallo, J.
A1 - Bolmont, J.
A1 - Bonanno, G.
A1 - Bonardi, A.
A1 - Bonev, T.
A1 - Bonifacio, P.
A1 - Bonnoli, G.
A1 - Bordas, Pol
A1 - Borgland, A. W.
A1 - Borkowski, Janett
A1 - Bose, R.
A1 - Botner, O.
A1 - Bottani, A.
A1 - Bouchet, L.
A1 - Bourgeat, M.
A1 - Boutonnet, C.
A1 - Bouvier, A.
A1 - Brau-Nogue, S.
A1 - Braun, I.
A1 - Bretz, T.
A1 - Briggs, M. S.
A1 - Bringmann, T.
A1 - Brook, P.
A1 - Brun, Pierre
A1 - Brunetti, L.
A1 - Buanes, T.
A1 - Buckley, J. H.
A1 - Buehler, R.
A1 - Bugaev, V.
A1 - Bulgarelli, A.
A1 - Bulik, Tomasz
A1 - Busetto, G.
A1 - Buson, S.
A1 - Byrum, K.
A1 - Cailles, M.
A1 - Cameron, R. A.
A1 - Camprecios, J.
A1 - Canestrari, R.
A1 - Cantu, S.
A1 - Capalbi, M.
A1 - Caraveo, P. A.
A1 - Carmona, E.
A1 - Carosi, A.
A1 - Carr, John
A1 - Carton, P. H.
A1 - Casanova, Sabrina
A1 - Casiraghi, M.
A1 - Catalano, O.
A1 - Cavazzani, S.
A1 - Cazaux, S.
A1 - Cerruti, M.
A1 - Chabanne, E.
A1 - Chadwick, Paula M.
A1 - Champion, C.
A1 - Chen, Andrew
A1 - Chiang, J.
A1 - Chiappetti, L.
A1 - Chikawa, M.
A1 - Chitnis, V. R.
A1 - Chollet, F.
A1 - Chudoba, J.
A1 - Cieslar, M.
A1 - Cillis, A. N.
A1 - Cohen-Tanugi, J.
A1 - Colafrancesco, Sergio
A1 - Colin, P.
A1 - Calome, J.
A1 - Colonges, S.
A1 - Compin, M.
A1 - Conconi, P.
A1 - Conforti, V.
A1 - Connaughton, V.
A1 - Conrad, Jan
A1 - Contreras, J. L.
A1 - Coppi, P.
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A1 - Viana, A.
A1 - Videla, M.
A1 - Vincent, P.
A1 - Vincent, S.
A1 - Vink, J.
A1 - Vlahakis, N.
A1 - Vlahos, L.
A1 - Vogler, P.
A1 - Vollhardt, A.
A1 - von Gunten, H. P.
A1 - Vorobiov, S.
A1 - Vuerli, C.
A1 - Waegebaert, V.
A1 - Wagner, R.
A1 - Wagner, R. G.
A1 - Wagner, S.
A1 - Wakely, S. P.
A1 - Walter, R.
A1 - Walther, T.
A1 - Warda, K.
A1 - Warwick, R.
A1 - Wawer, P.
A1 - Wawrzaszek, R.
A1 - Webb, N.
A1 - Wegner, P.
A1 - Weinstein, A.
A1 - Weitzel, Q.
A1 - Welsing, R.
A1 - Werner, M.
A1 - Wetteskind, H.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Wiesand, S.
A1 - Wilkinson, M.
A1 - Williams, D. A.
A1 - Willingale, R.
A1 - Winiarski, K.
A1 - Wischnewski, R.
A1 - Wisniewski, L.
A1 - Wood, M.
A1 - Woernlein, A.
A1 - Xiong, Q.
A1 - Yadav, K. K.
A1 - Yamamoto, H.
A1 - Yamamoto, T.
A1 - Yamazaki, R.
A1 - Yanagita, S.
A1 - Yebras, J. M.
A1 - Yelos, D.
A1 - Yoshida, A.
A1 - Yoshida, T.
A1 - Yoshikoshi, T.
A1 - Zabalza, V.
A1 - Zacharias, M.
A1 - Zajczyk, A.
A1 - Zanin, R.
A1 - Zdziarski, A.
A1 - Zech, Alraune
A1 - Zhao, A.
A1 - Zhou, X.
A1 - Zietara, K.
A1 - Ziolkowski, J.
A1 - Ziolkowski, P.
A1 - Zitelli, V.
A1 - Zurbach, C.
A1 - Zychowski, P.
T1 - Introducing the CTA concept
T2 - Astroparticle physics
N2 - The Cherenkov Telescope Array (CTA) is a new observatory for very high-energy (VHE) gamma rays. CTA has ambitions science goals, for which it is necessary to achieve full-sky coverage, to improve the sensitivity by about an order of magnitude, to span about four decades of energy, from a few tens of GeV to above 100 TeV with enhanced angular and energy resolutions over existing VHE gamma-ray observatories. An international collaboration has formed with more than 1000 members from 27 countries in Europe, Asia, Africa and North and South America. In 2010 the CTA Consortium completed a Design Study and started a three-year Preparatory Phase which leads to production readiness of CTA in 2014. In this paper we introduce the science goals and the concept of CTA, and provide an overview of the project.
KW - TeV gamma-ray astronomy
KW - Air showers
KW - Cherenkov Telescopes
Y1 - 2013
U6 - https://doi.org/10.1016/j.astropartphys.2013.01.007
SN - 0927-6505
SN - 1873-2852
VL - 43
IS - 2
SP - 3
EP - 18
PB - Elsevier
CY - Amsterdam
ER -
TY - JOUR
A1 - Warby, Jonathan
A1 - Zu, Fengshuo
A1 - Zeiske, Stefan
A1 - Gutierrez-Partida, Emilio
A1 - Frohloff, Lennart
A1 - Kahmann, Simon
A1 - Frohna, Kyle
A1 - Mosconi, Edoardo
A1 - Radicchi, Eros
A1 - Lang, Felix
A1 - Shah, Sahil
A1 - Pena-Camargo, Francisco
A1 - Hempel, Hannes
A1 - Unold, Thomas
A1 - Koch, Norbert
A1 - Armin, Ardalan
A1 - De Angelis, Filippo
A1 - Stranks, Samuel D.
A1 - Neher, Dieter
A1 - Stolterfoht, Martin
T1 - Understanding performance limiting interfacial recombination in pin Perovskite solar cells
JF - Advanced energy materials
N2 - Perovskite semiconductors are an attractive option to overcome the limitations of established silicon based photovoltaic (PV) technologies due to their exceptional opto-electronic properties and their successful integration into multijunction cells. However, the performance of single- and multijunction cells is largely limited by significant nonradiative recombination at the perovskite/organic electron transport layer junctions. In this work, the cause of interfacial recombination at the perovskite/C-60 interface is revealed via a combination of photoluminescence, photoelectron spectroscopy, and first-principle numerical simulations. It is found that the most significant contribution to the total C-60-induced recombination loss occurs within the first monolayer of C-60, rather than in the bulk of C-60 or at the perovskite surface. The experiments show that the C-60 molecules act as deep trap states when in direct contact with the perovskite. It is further demonstrated that by reducing the surface coverage of C-60, the radiative efficiency of the bare perovskite layer can be retained. The findings of this work pave the way toward overcoming one of the most critical remaining performance losses in perovskite solar cells.
KW - C60
KW - defects
KW - interface recombination
KW - loss mechanisms
KW - perovskites
KW - solar cells
Y1 - 2022
U6 - https://doi.org/10.1002/aenm.202103567
SN - 1614-6832
SN - 1614-6840
VL - 12
IS - 12
PB - Wiley-VCH
CY - Weinheim
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Acero, F.
A1 - Aharonian, Felix A.
A1 - Akhperjanian, A. G.
A1 - Anton, Gisela
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - de Almeida, U. Barres
A1 - Becherini, Yvonne
A1 - Becker, J.
A1 - Behera, B.
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Biteau, Jonathan
A1 - Bochow, A.
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Brucker, J.
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bulik, Tomasz
A1 - Buesching, I.
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chadwick, Paula M.
A1 - Charbonnier, A.
A1 - Chaves, Ryan C. G.
A1 - Cheesebrough, A.
A1 - Clapson, A. C.
A1 - Coignet, G.
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Dalton, M.
A1 - Daniel, M. K.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - Dickinson, H. J.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Drury, L. O'C.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Fallon, L.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, M.
A1 - Gallant, Y. A.
A1 - Gast, H.
A1 - Gerard, L.
A1 - Gerbig, D.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Glueck, B.
A1 - Goret, P.
A1 - Goering, D.
A1 - Haeffner, S.
A1 - Hague, J. D.
A1 - Hampf, D.
A1 - Hauser, M.
A1 - Heinz, S.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hinton, James Anthony
A1 - Hoffmann, A.
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, M.
A1 - Horns, D.
A1 - Jacholkowska, A.
A1 - de Jager, O. C.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Jung, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Keogh, D.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kneiske, T.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Kossakowski, R.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lennarz, D.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C. -C.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Masbou, J.
A1 - Maurin, D.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - McComb, T. J. L.
A1 - Medina, M. C.
A1 - Mehault, J.
A1 - Moderski, R.
A1 - Moulin, Emmanuel
A1 - Naumann, C. L.
A1 - Naumann-Godo, M.
A1 - de Naurois, M.
A1 - Nedbal, D.
A1 - Nekrassov, D.
A1 - Nguyen, N.
A1 - Nicholas, B.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Arribas, M. Paz
A1 - Pedaletti, G.
A1 - Pelletier, G.
A1 - Petrucci, P. -O.
A1 - Pita, S.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raue, M.
A1 - Rayner, S. M.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Ripken, J.
A1 - Rob, L.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Ruppel, J.
A1 - Sahakian, V.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schoeck, F. M.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sheidaei, F.
A1 - Skilton, J. L.
A1 - Sol, H.
A1 - Spengler, G.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Szostek, A.
A1 - Tavernet, J. -P.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Valerius, K.
A1 - van Eldik, C.
A1 - Vasileiadis, G.
A1 - Venter, C.
A1 - Vialle, J. P.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorobiov, S.
A1 - Vorster, M.
A1 - Wagner, S. J.
A1 - Ward, M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Zacharias, M.
A1 - Zajczyk, A.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H. -S.
A1 - Aleksic, J.
A1 - Antonelli, L. A.
A1 - Antoranz, P.
A1 - Backes, Michael
A1 - Barrio, J. A.
A1 - Bastieri, D.
A1 - Becerra Gonzalez, J.
A1 - Bednarek, W.
A1 - Berdyugin, A.
A1 - Berger, K.
A1 - Bernardini, E.
A1 - Biland, A.
A1 - Blanch Bigas, O.
A1 - Bock, R. K.
A1 - Boller, A.
A1 - Bonnoli, G.
A1 - Tridon, D. Borla
A1 - Braun, I.
A1 - Bretz, T.
A1 - Canellas, A.
A1 - Carmona, E.
A1 - Carosi, A.
A1 - Colin, P.
A1 - Colombo, E.
A1 - Contreras, J. L.
A1 - Cortina, J.
A1 - Cossio, L.
A1 - Covino, S.
A1 - Dazzi, F.
A1 - De Angelis, A.
A1 - De Cea del Pozo, E.
A1 - De Lotto, B.
A1 - Delgado Mendez, C.
A1 - Diago Ortega, A.
A1 - Doert, M.
A1 - Dominguez, A.
A1 - Prester, Dijana Dominis
A1 - Dorner, D.
A1 - Doro, M.
A1 - Elsaesser, D.
A1 - Ferenc, D.
A1 - Fonseca, M. V.
A1 - Font, L.
A1 - Fruck, C.
A1 - Garcia Lopez, R. J.
A1 - Garczarczyk, M.
A1 - Garrido, D.
A1 - Giavitto, G.
A1 - Godinovic, N.
A1 - Hadasch, D.
A1 - Haefner, D.
A1 - Herrero, A.
A1 - Hildebrand, D.
A1 - Hoehne-Moench, D.
A1 - Hose, J.
A1 - Hrupec, D.
A1 - Huber, B.
A1 - Jogler, T.
A1 - Klepser, S.
A1 - Kraehenbuehl, T.
A1 - Krause, J.
A1 - La Barbera, A.
A1 - Lelas, D.
A1 - Leonardo, E.
A1 - Lindfors, E.
A1 - Lombardi, S.
A1 - Lopez, M.
A1 - Lorenz, E.
A1 - Makariev, M.
A1 - Maneva, G.
A1 - Mankuzhiyil, N.
A1 - Mannheim, K.
A1 - Maraschi, L.
A1 - Mariotti, M.
A1 - Martinez, M.
A1 - Mazin, D.
A1 - Meucci, M.
A1 - Miranda, J. M.
A1 - Mirzoyan, R.
A1 - Miyamoto, H.
A1 - Moldon, J.
A1 - Moralejo, A.
A1 - Munar, P.
A1 - Nieto, D.
A1 - Nilsson, K.
A1 - Orito, R.
A1 - Oya, I.
A1 - Paneque, D.
A1 - Paoletti, R.
A1 - Pardo, S.
A1 - Paredes, J. M.
A1 - Partini, S.
A1 - Pasanen, M.
A1 - Pauss, F.
A1 - Perez-Torres, M. A.
A1 - Persic, M.
A1 - Peruzzo, L.
A1 - Pilia, M.
A1 - Pochon, J.
A1 - Prada, F.
A1 - Moroni, P. G. Prada
A1 - Prandini, E.
A1 - Puljak, I.
A1 - Reichardt, I.
A1 - Reinthal, R.
A1 - Rhode, W.
A1 - Ribo, M.
A1 - Rico, J.
A1 - Ruegamer, S.
A1 - Saggion, A.
A1 - Saito, K.
A1 - Saito, T. Y.
A1 - Salvati, M.
A1 - Satalecka, K.
A1 - Scalzotto, V.
A1 - Scapin, V.
A1 - Schultz, C.
A1 - Schweizer, T.
A1 - Shayduk, M.
A1 - Shore, S. N.
A1 - Sillanpaa, A.
A1 - Sitarek, J.
A1 - Sobczynska, D.
A1 - Spanier, F.
A1 - Spiro, S.
A1 - Stamerra, A.
A1 - Steinke, B.
A1 - Storz, J.
A1 - Strah, N.
A1 - Suric, T.
A1 - Takalo, L.
A1 - Takami, H.
A1 - Tavecchio, F.
A1 - Temnikov, P.
A1 - Terzic, T.
A1 - Tescaro, D.
A1 - Teshima, M.
A1 - Thom, M.
A1 - Tibolla, O.
A1 - Torres, D. F.
A1 - Treves, A.
A1 - Vankov, H.
A1 - Vogler, P.
A1 - Wagner, R. M.
A1 - Weitzel, Q.
A1 - Zabalza, V.
A1 - Zandanel, F.
A1 - Zanin, R.
A1 - Arlen, T.
A1 - Aune, T.
A1 - Beilicke, M.
A1 - Benbow, W.
A1 - Bouvier, A.
A1 - Bradbury, S. M.
A1 - Buckley, J. H.
A1 - Bugaev, V.
A1 - Byrum, K.
A1 - Cannon, A.
A1 - Cesarini, A.
A1 - Ciupik, L.
A1 - Connolly, M. P.
A1 - Cui, W.
A1 - Dickherber, R.
A1 - Duke, C.
A1 - Errando, M.
A1 - Falcone, A.
A1 - Finley, J. P.
A1 - Finnegan, G.
A1 - Fortson, L.
A1 - Furniss, A.
A1 - Galante, N.
A1 - Gall, D.
A1 - Godambe, S.
A1 - Griffin, S.
A1 - Grube, J.
A1 - Gyuk, G.
A1 - Hanna, D.
A1 - Holder, J.
A1 - Huan, H.
A1 - Hui, C. M.
A1 - Kaaret, P.
A1 - Karlsson, N.
A1 - Kertzman, M.
A1 - Khassen, Y.
A1 - Kieda, D.
A1 - Krawczynski, H.
A1 - Krennrich, F.
A1 - Lang, M. J.
A1 - LeBohec, S.
A1 - Maier, G.
A1 - McArthur, S.
A1 - McCann, A.
A1 - Moriarty, P.
A1 - Mukherjee, R.
A1 - Nunez, P. D.
A1 - Ong, R. A.
A1 - Orr, M.
A1 - Otte, A. N.
A1 - Park, N.
A1 - Perkins, J. S.
A1 - Pichel, A.
A1 - Pohl, Martin
A1 - Prokoph, H.
A1 - Ragan, K.
A1 - Reyes, L. C.
A1 - Reynolds, P. T.
A1 - Roache, E.
A1 - Rose, H. J.
A1 - Ruppel, J.
A1 - Schroedter, M.
A1 - Sembroski, G. H.
A1 - Sentuerk, G. D.
A1 - Telezhinsky, Igor O.
A1 - Tesic, G.
A1 - Theiling, M.
A1 - Thibadeau, S.
A1 - Varlotta, A.
A1 - Vassiliev, V. V.
A1 - Vivier, M.
A1 - Wakely, S. P.
A1 - Weekes, T. C.
A1 - Williams, D. A.
A1 - Zitzer, B.
A1 - de Almeida, U. Barres
A1 - Cara, M.
A1 - Casadio, C.
A1 - Cheung, C. C.
A1 - McConville, W.
A1 - Davies, F.
A1 - Doi, A.
A1 - Giovannini, G.
A1 - Giroletti, M.
A1 - Hada, K.
A1 - Hardee, P.
A1 - Harris, D. E.
A1 - Junor, W.
A1 - Kino, M.
A1 - Lee, N. P.
A1 - Ly, C.
A1 - Madrid, J.
A1 - Massaro, F.
A1 - Mundell, C. G.
A1 - Nagai, H.
A1 - Perlman, E. S.
A1 - Steele, I. A.
A1 - Walker, R. C.
A1 - Wood, D. L.
T1 - The 2010 very high energy gamma-ray flare and 10 years ofmulti-wavelength oservations of M 87
JF - The astrophysical journal : an international review of spectroscopy and astronomical physics
N2 - The giant radio galaxy M 87 with its proximity (16 Mpc), famous jet, and very massive black hole ((3-6) x 10(9) M-circle dot) provides a unique opportunity to investigate the origin of very high energy (VHE; E > 100 GeV) gamma-ray emission generated in relativistic outflows and the surroundings of supermassive black holes. M 87 has been established as a VHE gamma-ray emitter since 2006. The VHE gamma-ray emission displays strong variability on timescales as short as a day. In this paper, results from a joint VHE monitoring campaign on M 87 by the MAGIC and VERITAS instruments in 2010 are reported. During the campaign, a flare at VHE was detected triggering further observations at VHE (H.E.S.S.), X-rays (Chandra), and radio (43 GHz Very Long Baseline Array, VLBA). The excellent sampling of the VHE gamma-ray light curve enables one to derive a precise temporal characterization of the flare: the single, isolated flare is well described by a two-sided exponential function with significantly different flux rise and decay times of tau(rise)(d) = (1.69 +/- 0.30) days and tau(decay)(d) = (0.611 +/- 0.080) days, respectively. While the overall variability pattern of the 2010 flare appears somewhat different from that of previous VHE flares in 2005 and 2008, they share very similar timescales (similar to day), peak fluxes (Phi(>0.35 TeV) similar or equal to (1-3) x 10(-11) photons cm(-2) s(-1)), and VHE spectra. VLBA radio observations of 43 GHz of the inner jet regions indicate no enhanced flux in 2010 in contrast to observations in 2008, where an increase of the radio flux of the innermost core regions coincided with a VHE flare. On the other hand, Chandra X-ray observations taken similar to 3 days after the peak of the VHE gamma-ray emission reveal an enhanced flux from the core (flux increased by factor similar to 2; variability timescale <2 days). The long-term (2001-2010) multi-wavelength (MWL) light curve of M 87, spanning from radio to VHE and including data from Hubble Space Telescope, Liverpool Telescope, Very Large Array, and European VLBI Network, is used to further investigate the origin of the VHE gamma-ray emission. No unique, common MWL signature of the three VHE flares has been identified. In the outer kiloparsec jet region, in particular in HST-1, no enhanced MWL activity was detected in 2008 and 2010, disfavoring it as the origin of the VHE flares during these years. Shortly after two of the three flares (2008 and 2010), the X-ray core was observed to be at a higher flux level than its characteristic range (determined from more than 60 monitoring observations: 2002-2009). In 2005, the strong flux dominance of HST-1 could have suppressed the detection of such a feature. Published models for VHE gamma-ray emission from M 87 are reviewed in the light of the new data.
KW - galaxies: active
KW - galaxies: individual (M 87)
KW - galaxies: jets
KW - galaxies: nuclei
KW - gamma rays: galaxies
KW - radiation mechanisms: non-thermal
Y1 - 2012
U6 - https://doi.org/10.1088/0004-637X/746/2/151
SN - 0004-637X
VL - 746
IS - 2
PB - IOP Publ. Ltd.
CY - Bristol
ER -
TY - JOUR
A1 - Ahnen, M. L.
A1 - Ansoldi, S.
A1 - Antonelli, L. A.
A1 - Arcaro, C.
A1 - Babie, A.
A1 - Banerjee, B.
A1 - Bangale, P.
A1 - de Almeida, U. Barres
A1 - Barrio, J. A.
A1 - Gonzalez, J. Becerra
A1 - Bednarek, W.
A1 - Bernardini, E.
A1 - Berti, A.
A1 - Biasuzzi, B.
A1 - Biland, A.
A1 - Blanch, O.
A1 - Bonnefoy, S.
A1 - Bonnoli, G.
A1 - Borracci, F.
A1 - Carosi, R.
A1 - Carosi, A.
A1 - Chatterjee, A.
A1 - Colin, P.
A1 - Colombo, E.
A1 - Contreras, J. L.
A1 - Cortina, J.
A1 - Covino, S.
A1 - Cumani, P.
A1 - Da Vela, P.
A1 - Dazzi, F.
A1 - De Angelis, A.
A1 - De Lotto, B.
A1 - Wilhelmi, E. de Ona
A1 - Di Pierro, F.
A1 - Doert, M.
A1 - Dominguez, A.
A1 - Prester, D. Dominis
A1 - Dorner, D.
A1 - Doro, M.
A1 - Einecke, S.
A1 - Glawion, D. Eisenacher
A1 - Elsaesser, D.
A1 - Engelkemeier, M.
A1 - Ramazani, V. Fallah
A1 - Fernandez-Barra, A.
A1 - Fidalgo, D.
A1 - Fonseca, M. V.
A1 - Font, L.
A1 - Fruck, C.
A1 - Galindo, D.
A1 - Lopez, R. J. Garcia
A1 - Garczarczyk, M.
A1 - Gaug, M.
A1 - Giammaria, P.
A1 - Godinovie, N.
A1 - Gora, D.
A1 - Griffiths, S.
A1 - Guberman, D.
A1 - Hadasch, D.
A1 - Hahn, A.
A1 - Hassan, T.
A1 - Hayashida, M.
A1 - Herrera, J.
A1 - Hose, J.
A1 - Hrupec, D.
A1 - Hughes, G.
A1 - Ishio, K.
A1 - Konno, Y.
A1 - Kubo, H.
A1 - Kushida, J.
A1 - Kuvezdie, D.
A1 - Lelas, D.
A1 - Lindfors, E.
A1 - Lombardi, S.
A1 - Longo, F.
A1 - Lopez, M.
A1 - Lopez-Oramas, A.
A1 - Majumdar, P.
A1 - Makariev, M.
A1 - Maneva, G.
A1 - Manganaro, M.
A1 - Mannheim, K.
A1 - Maraschi, L.
A1 - Mariotti, M.
A1 - Martinez, M.
A1 - Mazin, D.
A1 - Menzel, U.
A1 - Minev, M.
A1 - Mirzoyan, R.
A1 - Moralejo, A.
A1 - Moreno, V.
A1 - Moretti, E.
A1 - Munar-Adrover, P.
A1 - Neustroev, V.
A1 - Niedzwiecki, A.
A1 - Rosillo, M. Nievas
A1 - Nilsson, K.
A1 - Nishijima, K.
A1 - Noda, K.
A1 - Nogues, L.
A1 - Paiano, S.
A1 - Palacio, J.
A1 - Paneque, D.
A1 - Paoletti, R.
A1 - Paredes, J. M.
A1 - Paredes-Fortuny, X.
A1 - Pedaletti, G.
A1 - Peresano, M.
A1 - Perri, L.
A1 - Persic, M.
A1 - Moroni, P. G. Prada
A1 - Prandini, E.
A1 - Puljak, I.
A1 - Garcia, J. R.
A1 - Reichardt, I.
A1 - Rhode, W.
A1 - Riti, M.
A1 - Rico, J.
A1 - Saito, T.
A1 - Satalecka, K.
A1 - Schroeder, S.
A1 - Schweizer, T.
A1 - Shore, S. N.
A1 - Sillanpaa, A.
A1 - Sitarek, J.
A1 - Sobczynskall, D.
A1 - Stamerra, A.
A1 - Strzys, M.
A1 - Surie, T.
A1 - Takalo, L.
A1 - Tavecchio, F.
A1 - Temnikov, P.
A1 - Terzie, T.
A1 - Tescaro, D.
A1 - Teshima, M.
A1 - Torres, D. F.
A1 - Torres-Alla, N.
A1 - Treves, A.
A1 - Vanzo, G.
A1 - Acosta, M. Vazquez
A1 - Vovk, I.
A1 - Ward, J. E.
A1 - Will, M.
A1 - Wu, M. H.
A1 - Zarie, D.
A1 - Abdalla, Hassan E.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Akhperjanian, A. G.
A1 - Andersson, T.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Arakawa, M.
A1 - Arrieta, M.
A1 - Aubert, P.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernlohr, K.
A1 - Blackwell, R.
A1 - Bottcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Btichele, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Carr, J.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Chretien, M.
A1 - Coffaro, M.
A1 - Colafrancesco, S.
A1 - Cologna, G.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Decock, J.
A1 - Degrange, B.
A1 - Dei, C.
A1 - Devin, J.
A1 - Dewilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Forster, A.
A1 - Funk, S.
A1 - Ftifiling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschal, D.
A1 - Goya, A.
A1 - Grondin, M. -H.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Iwasaki, H.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jogler, T.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzyfiski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluiniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Krtiger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lees, J. -P.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitche, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - De Naurois, M.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ott, S.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Pie, Q.
A1 - Pita, S.
A1 - Poon, H.
A1 - Prokhorov, D.
A1 - Prokoph, H.
A1 - Ptffilhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - De Los Reyes, R.
A1 - Richter, S.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Safi-Harb, S.
A1 - Sahakian, V.
A1 - Saito, S.
A1 - Salek, D.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schtissler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Settimo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Simoni, R.
A1 - So, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stycz, K.
A1 - Sushch, I.
A1 - Takahashi, T.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - Van der Walt, D. J.
A1 - Van Eldik, C.
A1 - Van Rensburg, C.
A1 - Van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Vok, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Wornlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zywuckan, N.
T1 - Constraints on particle acceleration in SS433/W50 from MAGIC and HESS observations
JF - Astronomy and astrophysics : an international weekly journal
N2 - Context. The large jet kinetic power and non-thermal processes occurring in the microquasar SS 433 make this source a good candidate for a very high-energy (VHE) gamma-ray emitter. Gamma-ray fluxes above the sensitivity limits of current Cherenkov telescopes have been predicted for both the central X-ray binary system and the interaction regions of SS 433 jets with the surrounding W50 nebula. Non-thermal emission at lower energies has been previously reported, indicating that efficient particle acceleration is taking place in the system. Aims. We explore the capability of SS 433 to emit VHE gamma rays during periods in which the expected flux attenuation due to periodic eclipses (P-orb similar to 13.1 days) and precession of the circumstellar disk (P-pre similar to 162 days) periodically covering the central binary system is expected to be at its minimum. The eastern and western SS 433/W50 interaction regions are also examined using the whole data set available. We aim to constrain some theoretical models previously developed for this system with our observations. Methods. We made use of dedicated observations from the Major Atmospheric Gamma Imaging Cherenkov telescopes (MAGIC) and High Energy Spectroscopic System (H.E.S.S.) of SS 433 taken from 2006 to 2011. These observation were combined for the first time and accounted for a total effective observation time of 16.5 h, which were scheduled considering the expected phases of minimum absorption of the putative VHE emission. Gamma-ray attenuation does not affect the jet/medium interaction regions. In this case, the analysis of a larger data set amounting to similar to 40-80 h, depending on the region, was employed. Results. No evidence of VHE gamma-ray emission either from the central binary system or from the eastern/western interaction regions was found. Upper limits were computed for the combined data set. Differential fluxes from the central system are found to be less than or similar to 10(-12)-10(-13) TeV-1 cm(-2) s(-1) in an energy interval ranging from similar to few x 100 GeV to similar to few TeV. Integral flux limits down to similar to 10(-12)-10(-13) ph cm(-2) s(-1) and similar to 10(-13)-10(-14) ph cm(-2) s(-1) are obtained at 300 and 800 GeV, respectively. Our results are used to place constraints on the particle acceleration fraction at the inner jet regions and on the physics of the jet/medium interactions. Conclusions. Our findings suggest that the fraction of the jet kinetic power that is transferred to relativistic protons must be relatively small in SS 433, q(p) <= 2.5 x 10(-5), to explain the lack of TeV and neutrino emission from the central system. At the SS 433/W50 interface, the presence of magnetic fields greater than or similar to 10 mu G is derived assuming a synchrotron origin for the observed X-ray emission. This also implies the presence of high-energy electrons with E-e up to 50 TeV, preventing an efficient production of gamma-ray fluxes in these interaction regions.
KW - gamma rays: general
KW - stars: black holes
KW - X-rays: binaries
KW - ISM: jets and outflows
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201731169
SN - 1432-0746
VL - 612
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Adam, R.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Angüner, Ekrem Oǧuzhan
A1 - Arakawa, M.
A1 - Arcaro, C.
A1 - Armand, C.
A1 - Ashkar, H.
A1 - Backes, M.
A1 - Martins, V. Barbosa
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Berge, D.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Böttcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bonnefoy, S.
A1 - Bregeon, J.
A1 - Breuhaus, M.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Büchele, M.
A1 - Bulik, T.
A1 - Bylund, T.
A1 - Capasso, M.
A1 - Caroff, S.
A1 - Carosi, A.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chand, T.
A1 - Chandra, S.
A1 - Chen, A.
A1 - Colafrancesco, S.
A1 - Curylo, M.
A1 - Davids, I. D.
A1 - Deil, C.
A1 - Devin, J.
A1 - DeWilt, P.
A1 - Dirson, L.
A1 - Djannati-Ata, A.
A1 - Dmytriiev, A.
A1 - Donath, A.
A1 - Doroshenko, V
A1 - Dyks, J.
A1 - Egberts, Kathrin
A1 - Emery, G.
A1 - Ernenwein, J-P
A1 - Eschbach, S.
A1 - Feijen, K.
A1 - Fegan, S.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Funk, S.
A1 - Füßling, Matthias
A1 - Gabici, S.
A1 - Gallant, Y. A.
A1 - Gate, F.
A1 - Giavitto, G.
A1 - Glawion, D.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M-H
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holch, Tim Lukas
A1 - Holler, M.
A1 - Horns, D.
A1 - Huber, D.
A1 - Iwasaki, H.
A1 - Jamrozy, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jardin-Blicq, A.
A1 - Jung-Richardt, I
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - King, J.
A1 - Klepser, S.
A1 - Kluzniak, W.
A1 - Komin, Nu
A1 - Kosack, K.
A1 - Kostunin, D.
A1 - Kraus, M.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J-P
A1 - Leser, Eva
A1 - Levy, C.
A1 - Lohse, T.
A1 - Lypova, I
A1 - Mackey, J.
A1 - Majumdar, J.
A1 - Malyshev, D.
A1 - Marandon, V
A1 - Marcowith, Alexandre
A1 - Mares, A.
A1 - Mariaud, C.
A1 - Marti-Devesa, G.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Meintjes, P. J.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Moore, C.
A1 - Moulin, Emmanuel
A1 - Muller, J.
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Ndiyavala, H.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Wilhelmi, E. de Ona
A1 - Ostrowski, M.
A1 - Oya, I
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Perennes, C.
A1 - Petrucci, P-O
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poireau, V
A1 - Priyana Noel, A.
A1 - Prokhorov, D. A.
A1 - Prokoph, H.
A1 - Pühlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Rauth, R.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Remy, Q.
A1 - Renaud, M.
A1 - Rieger, F.
A1 - Rinchiuso, L.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Ruiz-Velasco, E.
A1 - Sahakian, V
A1 - Saito, S.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schüssler, F.
A1 - Schulz, A.
A1 - Schutte, H.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Senniappan, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shiningayamwe, K.
A1 - Simoni, R.
A1 - Sinha, A.
A1 - Sol, H.
A1 - Specovius, A.
A1 - Spir-Jacob, M.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Steppa, Constantin Beverly
A1 - Takahashi, T.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsirou, M.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van Der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Yang, R.
A1 - Yoneda, H.
A1 - Zacharias, Michael
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Ziegler, A.
A1 - Zorn, J.
A1 - Zywucka, N.
A1 - Meyer, M.
T1 - Constraints on the emission region of 3C 279 during strong flares in 2014 and 2015 through VHE gamma-ray observations with HESS
JF - Astronomy and astrophysics : an international weekly journal
N2 - The flat spectrum radio quasar 3C 279 is known to exhibit pronounced variability in the high-energy (100MeV < E < 100 GeV) gamma-ray band, which is continuously monitored with Fermi-LAT. During two periods of high activity in April 2014 and June 2015 target-of-opportunity observations were undertaken with the High Energy Stereoscopic System (H.E.S.S.) in the very-high-energy (VHE, E > 100 GeV) gamma-ray domain. While the observation in 2014 provides an upper limit, the observation in 2015 results in a signal with 8 : 7 sigma significance above an energy threshold of 66 GeV. No VHE variability was detected during the 2015 observations. The VHE photon spectrum is soft and described by a power-law index of 4.2 +/- 0.3. The H.E.S.S. data along with a detailed and contemporaneous multiwavelength data set provide constraints on the physical parameters of the emission region. The minimum distance of the emission region from the central black hole was estimated using two plausible geometries of the broad-line region and three potential intrinsic spectra. The emission region is confidently placed at r greater than or similar to 1 : 7 X 1017 cm from the black hole, that is beyond the assumed distance of the broad-line region. Time-dependent leptonic and lepto-hadronic one-zone models were used to describe the evolution of the 2015 flare. Neither model can fully reproduce the observations, despite testing various parameter sets. Furthermore, the H.E.S.S. data were used to derive constraints on Lorentz invariance violation given the large redshift of 3C 279.
KW - radiation mechanisms: non-thermal
KW - quasars: individual: 3C 279
KW - galaxies: active
KW - relativistic processes
Y1 - 2019
U6 - https://doi.org/10.1051/0004-6361/201935704
SN - 1432-0746
VL - 627
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abdalla, Hassan E.
A1 - Collaboration, H. E. S. S.
A1 - Abramowski, A.
A1 - Aharonian, Felix A.
A1 - Benkhali, F. Ait
A1 - Angüner, Ekrem Oǧuzhan
A1 - Arakawa, M.
A1 - Armand, C.
A1 - Arrieta, M.
A1 - Backes, M.
A1 - Balzer, A.
A1 - Barnard, M.
A1 - Becherini, Y.
A1 - Tjus, J. Becker
A1 - Berge, D.
A1 - Bernhard, S.
A1 - Bernloehr, K.
A1 - Blackwell, R.
A1 - Bottcher, M.
A1 - Boisson, C.
A1 - Bolmont, J.
A1 - Bonnefoy, S.
A1 - Bordas, Pol
A1 - Bregeon, J.
A1 - Brun, F.
A1 - Brun, P.
A1 - Bryan, M.
A1 - Buechele, M.
A1 - Bulik, T.
A1 - Capasso, M.
A1 - Caroff, S.
A1 - Carosi, A.
A1 - Casanova, Sabrina
A1 - Cerruti, M.
A1 - Chakraborty, N.
A1 - Chaves, R. C. G.
A1 - Chen, A.
A1 - Chevalier, J.
A1 - Colafrancesco, S.
A1 - Condon, B.
A1 - Conrad, J.
A1 - Davids, I. D.
A1 - Decock, J.
A1 - Deil, C.
A1 - Devin, J.
A1 - deWilt, P.
A1 - Dirson, L.
A1 - Djannati-Atai, A.
A1 - Donath, A.
A1 - Dyks, J.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Emery, G.
A1 - Ernenwein, J. -P.
A1 - Eschbach, S.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Fernandes, M. V.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Funk, S.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Gate, F.
A1 - Giavitto, G.
A1 - Glawion, D.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M. -H.
A1 - Hahn, J.
A1 - Haupt, M.
A1 - Hawkes, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hinton, J. A.
A1 - Hofmann, W.
A1 - Hoischen, Clemens
A1 - Holch, T. L.
A1 - Holler, M.
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Iwasaki, H.
A1 - Jacholkowska, A.
A1 - Jamrozy, M.
A1 - Jankowsky, D.
A1 - Jankowsky, F.
A1 - Jingo, M.
A1 - Jouvin, L.
A1 - Jung-Richardt, I.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katsuragawa, M.
A1 - Katz, U.
A1 - Kerszberg, D.
A1 - Khangulyan, D.
A1 - Khelifi, B.
A1 - King, J.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Komin, Nu.
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Kraus, M.
A1 - Kruger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lau, J.
A1 - Lefaucheur, J.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. -P.
A1 - Leser, Eva
A1 - Lohse, T.
A1 - Lorentz, M.
A1 - Liu, R.
A1 - Lopez-Coto, R.
A1 - Lypova, I.
A1 - Malyshev, D.
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Mariaud, C.
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, M.
A1 - Meintjes, P. J.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mohrmann, L.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - Nakashima, S.
A1 - de Naurois, M.
A1 - Ndiyavala, H.
A1 - Niederwanger, F.
A1 - Niemiec, J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Padovani, M.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Perennes, C.
A1 - Petrucci, P. -O.
A1 - Peyaud, B.
A1 - Piel, Q.
A1 - Pita, S.
A1 - Poireau, V.
A1 - Prokhorov, D. A.
A1 - Prokoph, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Rauth, R.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Rinchiuso, L.
A1 - Romoli, C.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Saito, S.
A1 - Sanchez, D. A.
A1 - Santangelo, Andrea
A1 - Sasaki, M.
A1 - Schlickeiser, R.
A1 - Schussler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwemmer, S.
A1 - Seglar-Arroyo, M.
A1 - Seyffert, A. S.
A1 - Shafi, N.
A1 - Shilon, I.
A1 - Shiningayamwe, K.
A1 - Simoni, R.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spir-Jacob, M.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Steppa, Constantin Beverly
A1 - Sushch, I.
A1 - Takahashi, T.
A1 - Tavernet, J. -P.
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tibaldo, L.
A1 - Tiziani, D.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Tsirou, M.
A1 - Tsuji, N.
A1 - Tuffs, R.
A1 - Uchiyama, Y.
A1 - van der Walt, D. J.
A1 - van Eldik, C.
A1 - van Rensburg, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voisin, F.
A1 - Voelk, H. J.
A1 - Vuillaume, T.
A1 - Wadiasingh, Z.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zanin, R.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zefi, F.
A1 - Ziegler, A.
A1 - Zorn, J.
A1 - Zywucka, N.
T1 - Detection of variable VHE gamma-ray emission from the extra-galactic gamma-ray binary LMC P3
JF - Astronomy and astrophysics : an international weekly journal
N2 - Context. Recently, the high-energy (HE, 0.1-100 GeV) gamma-ray emission from the object LMC P3 in the Large Magellanic Cloud (LMC) has been discovered to be modulated with a 10.3-day period, making it the first extra-galactic gamma-ray binary. Aims. This work aims at the detection of very-high-energy (VHE, >100 GeV) gamma-ray emission and the search for modulation of the VHE signal with the orbital period of the binary system. Methods. LMC P3 has been observed with the High Energy Stereoscopic System (H.E.S.S.); the acceptance-corrected exposure time is 100 h. The data set has been folded with the known orbital period of the system in order to test for variability of the emission. Results. VHE gamma-ray emission is detected with a statistical significance of 6.4 sigma. The data clearly show variability which is phase-locked to the orbital period of the system. Periodicity cannot be deduced from the H.E.S.S. data set alone. The orbit-averaged luminosity in the 1-10 TeV energy range is (1.4 +/- 0.2) x 10(35) erg s(-1). A luminosity of (5 +/- 1) x 10(35) erg s(-1) is reached during 20% of the orbit. HE and VHE gamma-ray emissions are anti-correlated. LMC P3 is the most luminous gamma-ray binary known so far.
KW - gamma rays: stars
KW - binaries: general
KW - stars: massive
Y1 - 2018
U6 - https://doi.org/10.1051/0004-6361/201732426
SN - 1432-0746
VL - 610
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Abramowski, Attila
A1 - Aharonian, Felix A.
A1 - Benkhali, Faical Ait
A1 - Akhperjanian, A. G.
A1 - Angüner, Ekrem Oǧuzhan
A1 - Backes, Michael
A1 - Balenderan, Shangkari
A1 - Balzer, Arnim
A1 - Barnacka, Anna
A1 - Becherini, Yvonne
A1 - Tjus, J. Becker
A1 - Berge, David
A1 - Bernhard, Sabrina
A1 - Bernlöhr, K.
A1 - Birsin, E.
A1 - Biteau, Jonathan
A1 - Boettcher, Markus
A1 - Boisson, Catherine
A1 - Bolmont, J.
A1 - Bordas, Pol
A1 - Bregeon, Johan
A1 - Brun, Francois
A1 - Brun, Pierre
A1 - Bryan, Mark
A1 - Bulik, Tomasz
A1 - Carrigan, Svenja
A1 - Casanova, Sabrina
A1 - Chadwick, Paula M.
A1 - Chatraborty, N.
A1 - Chalme-Calvet, R.
A1 - Chaves, Ryan C. G.
A1 - Chretien, M.
A1 - Colafrancesco, Sergio
A1 - Cologna, Gabriele
A1 - Conrad, Jan
A1 - Couturier, C.
A1 - Cui, Y.
A1 - Davids, I. D.
A1 - Degrange, B.
A1 - Deil, C.
A1 - deWilt, P.
A1 - Djannati-Ataï, A.
A1 - Domainko, W.
A1 - Donath, A.
A1 - Dubus, G.
A1 - Dutson, K.
A1 - Dyks, J.
A1 - Dyrda, M.
A1 - Edwards, T.
A1 - Egberts, Kathrin
A1 - Eger, P.
A1 - Espigat, P.
A1 - Farnier, C.
A1 - Fegan, S.
A1 - Feinstein, F.
A1 - Fernandes, M. V.
A1 - Fernandez, D.
A1 - Fiasson, A.
A1 - Fontaine, G.
A1 - Foerster, A.
A1 - Fuessling, M.
A1 - Gabici, S.
A1 - Gajdus, M.
A1 - Gallant, Y. A.
A1 - Garrigoux, T.
A1 - Giavitto, G.
A1 - Giebels, B.
A1 - Glicenstein, J. F.
A1 - Gottschall, D.
A1 - Grondin, M. -H.
A1 - Grudzinska, M.
A1 - Hadasch, D.
A1 - Haeffner, S.
A1 - Hahn, J.
A1 - Harris, J.
A1 - Heinzelmann, G.
A1 - Henri, G.
A1 - Hermann, G.
A1 - Hervet, O.
A1 - Hillert, A.
A1 - Hinton, James Anthony
A1 - Hofmann, W.
A1 - Hofverberg, P.
A1 - Holler, Markus
A1 - Horns, D.
A1 - Ivascenko, A.
A1 - Jacholkowska, A.
A1 - Jahn, C.
A1 - Jamrozy, M.
A1 - Janiak, M.
A1 - Jankowsky, F.
A1 - Jung-Richardt, O.
A1 - Kastendieck, M. A.
A1 - Katarzynski, K.
A1 - Katz, U.
A1 - Kaufmann, S.
A1 - Khelifi, B.
A1 - Kieffer, M.
A1 - Klepser, S.
A1 - Klochkov, D.
A1 - Kluzniak, W.
A1 - Kolitzus, D.
A1 - Komin, Nu
A1 - Kosack, K.
A1 - Krakau, S.
A1 - Krayzel, F.
A1 - Krueger, P. P.
A1 - Laffon, H.
A1 - Lamanna, G.
A1 - Lefaucheur, J.
A1 - Lefranc, V.
A1 - Lemiere, A.
A1 - Lemoine-Goumard, M.
A1 - Lenain, J. P.
A1 - Lohse, T.
A1 - Lopatin, A.
A1 - Lu, C-C
A1 - Marandon, V.
A1 - Marcowith, Alexandre
A1 - Marx, R.
A1 - Maurin, G.
A1 - Maxted, N.
A1 - Mayer, Markus
A1 - McComb, T. J. L.
A1 - Mehault, J.
A1 - Meintjes, P. J.
A1 - Menzler, U.
A1 - Meyer, M.
A1 - Mitchell, A. M. W.
A1 - Moderski, R.
A1 - Mohamed, M.
A1 - Mora, K.
A1 - Moulin, Emmanuel
A1 - Murach, T.
A1 - de Naurois, M.
A1 - Niemiec, J.
A1 - Nolan, S. J.
A1 - Oakes, L.
A1 - Odaka, H.
A1 - Ohm, S.
A1 - Opitz, B.
A1 - Ostrowski, M.
A1 - Oya, I.
A1 - Panter, M.
A1 - Parsons, R. D.
A1 - Anibas, M. Paz
A1 - Pekeur, N. W.
A1 - Pelletier, G.
A1 - Petrucci, P-O
A1 - Peyaud, B.
A1 - Pita, S.
A1 - Poon, H.
A1 - Puehlhofer, G.
A1 - Punch, M.
A1 - Quirrenbach, A.
A1 - Raab, S.
A1 - Reichardt, I.
A1 - Reimer, A.
A1 - Reimer, O.
A1 - Renaud, M.
A1 - de los Reyes, R.
A1 - Rieger, F.
A1 - Romoli, C.
A1 - Rosier-Lees, S.
A1 - Rowell, G.
A1 - Rudak, B.
A1 - Rulten, C. B.
A1 - Sahakian, V.
A1 - Salek, D.
A1 - Sanchez, David M.
A1 - Santangelo, Andrea
A1 - Schlickeiser, R.
A1 - Schuessler, F.
A1 - Schulz, A.
A1 - Schwanke, U.
A1 - Schwarzburg, S.
A1 - Schwemmer, S.
A1 - Sol, H.
A1 - Spanier, F.
A1 - Spengler, G.
A1 - Spies, F.
A1 - Stawarz, L.
A1 - Steenkamp, R.
A1 - Stegmann, Christian
A1 - Stinzing, F.
A1 - Stycz, K.
A1 - Sushch, Iurii
A1 - Tavernet, J-P
A1 - Tavernier, T.
A1 - Taylor, A. M.
A1 - Terrier, R.
A1 - Tluczykont, M.
A1 - Trichard, C.
A1 - Valerius, K.
A1 - van Eldik, C.
A1 - van Soelen, B.
A1 - Vasileiadis, G.
A1 - Veh, J.
A1 - Venter, C.
A1 - Viana, A.
A1 - Vincent, P.
A1 - Vink, J.
A1 - Voelk, H. J.
A1 - Volpe, F.
A1 - Vorster, M.
A1 - Vuillaume, T.
A1 - Wagner, S. J.
A1 - Wagner, P.
A1 - Wagner, R. M.
A1 - Ward, M.
A1 - Weidinger, M.
A1 - Weitzel, Q.
A1 - White, R.
A1 - Wierzcholska, A.
A1 - Willmann, P.
A1 - Woernlein, A.
A1 - Wouters, D.
A1 - Yang, R.
A1 - Zabalza, V.
A1 - Zaborov, D.
A1 - Zacharias, M.
A1 - Zdziarski, A. A.
A1 - Zech, Alraune
A1 - Zechlin, H-S
T1 - HESS detection of TeV emission from the interaction region between the supernova remnant G349.7+0.2 and a molecular cloud
JF - Astronomy and astrophysics : an international weekly journal
N2 - G349.7+0.2 is a young Galactic supernova remnant (SNR) located at the distance of 11.5 kpc and observed across the entire electromagnetic spectrum from radio to high energy (HE; 0.1 GeV < E < 100 GeV) gamma-rays. Radio and infrared observations indicate that the remnant is interacting with a molecular cloud. In this paper, the detection of very high energy (VHE, E > 100 GeV) gamma-ray emission coincident with this SNR with the High Energy Stereoscopic System (HESS.) is reported. This makes it one of the farthest Galactic SNR ever detected in this domain. An integral flux F(E > 400 GeV) = (6.5 +/- 1.1(stat) +/- 1.3(syst)) x 10-11 ph cm(-2) s(-1) corresponding to similar to 0.7% of that of the Crab Nebula and to a luminosity of similar to 10(34) erg s(-1) above the same energy threshold, and a steep photon index Gamma(VHE) = 2.8 +/- 0.27(stat) +/- 0.20(syst) are measured. The analysis of more than 5 yr of Fermi-LAT data towards this source shows a power-law like spectrum with a best-fit photon index Gamma(HE) = 2.2 +/- 0.04.2(stat-0.31sys)(+0.13), The combined gamma-ray spectrum of 0349.7+0.2 can be described by either a broken power law (I3PL) or a power law with exponential (or sub exponential) cutoff (PLC). In the former case, the photon break energy is found at E-br,E-gamma = 551(-30)(+70) GeV, slightly higher than what is usually observed in the HE/VHE gamma-ray emitting middle-aged SNRs known to be interacting with molecular clouds. In the latter case. the exponential (respectively sub-exponential) cutoff energy is measured at E-cat,E-gamma = 1.4(-0.55)(+1.6) (respectively 0.35(-0.21)(+0.75)) TeV. A pion decay process resulting from the interaction of the accelerated protons and nuclei with the dense surrounding medium is clearly the preferred scenario to explain the gamma-ray emission. The BPL with a spectral steepening of 0.5-1 and the PLC provide equally good fits to the data. The product or the average gas density and the total energy content of accelerated protons and nuclei amounts to nu W-p similar to 5 x 10(51) erg cm(-3)
KW - gamma rays: general
KW - ISM: supernova remnants
KW - ISM: clouds
Y1 - 2015
U6 - https://doi.org/10.1051/0004-6361/201425070
SN - 0004-6361
SN - 1432-0746
VL - 574
PB - EDP Sciences
CY - Les Ulis
ER -
TY - THES
A1 - Foster, Mary Grace
T1 - X-Ray studies of exoplanet systems
N2 - X-rays are integral to furthering our knowledge of exoplanetary systems. In this work we discuss the use of X-ray observations to understand star-planet interac- tions, mass-loss rates of an exoplanet’s atmosphere and the study of an exoplanet’s atmospheric components using future X-ray spectroscopy.
The low-mass star GJ 1151 was reported to display variable low-frequency radio emission, which is an indication of coronal star-planet interactions with an unseen exoplanet. In chapter 5 we report the first X-ray detection of GJ 1151’s corona based on XMM-Newton data. Averaged over the observation, we detect the star with a low coronal temperature of 1.6 MK and an X-ray luminosity of LX = 5.5 × 1026 erg/s. This is compatible with the coronal assumptions for a sub-Alfvénic star- planet interaction origin of the observed radio signals from this star.
In chapter 6, we aim to characterise the high-energy environment of known ex- oplanets and estimate their mass-loss rates. This work is based on the soft X-ray instrument on board the Spectrum Roentgen Gamma (SRG) mission, eROSITA, along with archival data from ROSAT, XMM-Newton, and Chandra. We use these four X-ray source catalogues to derive X-ray luminosities of exoplanet host stars in the 0.2-2 keV energy band. A catalogue of the mass-loss rates of 287 exoplan- ets is presented, with 96 of these planets characterised for the first time using new eROSITA detections. Of these first time detections, 14 are of transiting exoplanets that undergo irradiation from their host stars that is of a level known to cause ob- servable evaporation signals in other systems, making them suitable for follow-up observations.
In the next generation of space observatories, X-ray transmission spectroscopy of an exoplanet’s atmosphere will be possible, allowing for a detailed look into the atmospheric composition of these planets. In chapter 7, we model sample spectra using a toy model of an exoplanetary atmosphere to predict what exoplanet transit observations with future X-ray missions such as Athena will look like. We then estimate the observable X-ray transmission spectrum for a typical Hot Jupiter-type exoplanet, giving us insights into the advances in X-ray observations of exoplanets in the decades to come.
N2 - Röntgenstrahlen sind ein wesentlicher Bestandteil, um unser Wissen über extrasolare Planetensysteme zu vertiefen und zu erweitern. In dieser Arbeit erörtern wir den Einsatz von Röntgenbeobachtungen zum Verständnis von Stern-Planeten-Interaktionen, der Abschätzung von Massenverlustraten von Exoplanetenatmosphären und die Untersuchung der atmosphärischen Komponenten eines Exoplaneten mithilfe zukünftiger Röntgenspektroskopie.
Beobachtungen des massearmen Sterns GJ 1151 deuten auf eine variable Emission niederfrequenter Radiostrahlung hin, was als Indiz für koronale Stern-Planeten-Wechselwirkungen mit einem unsichtbaren Exoplaneten angesehen wird. In Kapitel 5 berichten wir über den ersten Röntgennachweis der Korona von GJ 1151, basierend auf XMM-Newton Daten. Über die gesamte Beobachtungsdauer gemittelt, weisen wir den Stern mit einer niedrigen koronalen Temperatur von 1,6 MK und einer Röntgenluminosität von LX = 5, 5 ◊ 1026 erg/s nach. Dieser Nachweis im Röntgenlicht ist kompatibel mit der Annahme, dass sub-Alfvénische Wechselwirkungen zwischen stellarer Corona und Exoplanet die Ursache für die beobachteten Radiosignale des Sterns sind.
Kapitel 6 zielt darauf ab, die hochenergetische Umgebung bekannter Exoplaneten zu charakterisieren und die Massenverlustraten der Planetenatmosphären abzuschätzen. Diese Arbeit basiert auf neu gewonnenen Daten des Instruments für weiche Röntgenstrahlung an Bord der Spectrum Roentgen Gamma (SRG) Mission, eROSITA, und wird komplementiert von Archivdaten von ROSAT, XMM-Newton und Chandra. Mithilfe dieser vier Röntgenquellenkataloge vermessen wir die Röntgenhelligkeit der Zentralsterne von bekannten Exoplanetensytemen im Energiebereich von 0,2-2 keV. Die Ergebnisse sind zusammen mit den errechneten Massenverlustraten von 287 Exoplaneten in einem Katalog zusammengefasst, darunter 96 Planeten, die zum ersten Mal durch neue eROSITA-Nachweise charakterisiert wurden. Bei 14 dieser Erstnachweise handelt es sich um transitierende Exoplaneten, die von ihrem Heimatstern so stark bestrahlt werden, dass beobachtbare Signale, ausgelöst durch die Verdampfung ihrer Atmosphäre, zu erwarten sind. Speziell diese Systeme eignen sich besonders für Folgebeobachtungen.
Mit der nächsten Generation von Weltraumobservatorien wird die Röntgentransmissionsspektroskopie von extrasolaren Planetenatmosphären möglich sein, was nie dagewesene Details über die atmosphärische Zusammensetzung dieser Planeten ans Licht bringen wird. In Kapitel 7 modellieren wir Transmissionsspektren mithilfe eines vereinfachten Modells einer Exoplanetenatmosphäre um vorherzusagen, wie Transitbeobachtungen von Exoplaneten mit zukünftigen Röntgenmissionen wie Athena aussehen werden. Wir schätzen dann das beobachtbare Röntgentransmissionsspektrum für einen typischen Exoplaneten vom Typ Hot Jupiter ab, was uns einen Einblick in die zu erwartenden Fortschritte bei der Röntgenbeobachtung von Exoplaneten in den kommenden Jahrzehnten gibt.
KW - exoplanets
KW - x-rays
KW - stellar physics
KW - Exoplaneten
KW - Röntgenstrahlen
KW - stellare Physik
Y1 - 2022
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-562152
PB - xiii, 92
ER -
TY - JOUR
A1 - Schwope, Axel
A1 - Pires, Adriana M.
A1 - Kurpas, Jan
A1 - Doroshenko, Victor
A1 - Suleimanov, Valery F.
A1 - Freyberg, Michael
A1 - Becker, Werner
A1 - Dennerl, Konrad
A1 - Haberl, Frank
A1 - Lamer, Georg
A1 - Maitra, Chandreyee
A1 - Potekhin, Alexander Y.
A1 - Ramos-Ceja, Miriam E.
A1 - Santangelo, Andrea
A1 - Traulsen, Iris
A1 - Werner, Klaus
T1 - Phase-resolved X-ray spectroscopy of PSR B0656+14 with SRG/eROSITA and XMM-Newton
JF - Astronomy and astrophysics : an international weekly journal
N2 - We present a detailed spectroscopic and timing analysis of X-ray observations of the bright pulsar PSR B0656+14. The observations were obtained simultaneously with eROSITA and XMM-Newton during the calibration and performance verification phase of the Spektrum-Roentgen-Gamma mission (SRG). The analysis of the 100 ks deep observation of eROSITA is supported by archival observations of the source, including XMM-Newton, NuSTAR, and NICER. Using XMM-Newton and NICER, we first established an X-ray ephemeris for the time interval 2015 to 2020, which connects all X-ray observations in this period without cycle count alias and phase shifts. The mean eROSITA spectrum clearly reveals an absorption feature originating from the star at 570 eV with a Gaussian sigma of about 70 eV that was tentatively identified in a previous long XMM-Newton observation. A second previously discussed absorption feature occurs at 260-265 eV and is described here as an absorption edge. It could be of atmospheric or of instrumental origin. These absorption features are superposed on various emission components that are phenomenologically described here as the sum of hot (120 eV) and cold (65 eV) blackbody components, both of photospheric origin, and a power law with photon index Gamma = 2 from the magnetosphere. We created energy-dependent light curves and phase-resolved spectra with a high signal-to-noise ratio. The phase-resolved spectroscopy reveals that the Gaussian absorption line at 570 eV is clearly present throughout similar to 60% of the spin cycle, but it is otherwise undetected. Likewise, its parameters were found to be dependent on phase. The visibility of the line strength coincides in phase with the maximum flux of the hot blackbody. If the line originates from the stellar surface, it nevertheless likely originates from a different location than the hot polar cap. We also present three families of model atmospheres: a magnetized atmosphere, a condensed surface, and a mixed model. They were applied to the mean observed spectrum, whose continuum fit the observed data well. The atmosphere model, however, predicts distances that are too short. For the mixed model, the Gaussian absorption may be interpreted as proton cyclotron absorption in a field as high as 10(14) G, which is significantly higher than the field derived from the moderate observed spin-down.
KW - stars: neutron
KW - X-rays: stars
KW - pulsars: individual: PSR B0656+14
Y1 - 2022
U6 - https://doi.org/10.1051/0004-6361/202141105
SN - 0004-6361
SN - 1432-0746
VL - 661
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Foster, Mary Grace
A1 - Poppenhäger, Katja
A1 - Ilić Petković, Nikoleta
A1 - Schwope, Axel
T1 - Exoplanet X-ray irradiation and evaporation rates with eROSITA
JF - Astronomy and astrophysics : an international weekly journal
N2 - High-energy irradiation is a driver for atmospheric evaporation and mass loss in exoplanets. This work is based on data from eROSITA, the soft X-ray instrument on board the Spectrum Roentgen Gamma mission, as well as on archival data from other missions. We aim to characterise the high-energy environment of known exoplanets and estimate their mass-loss rates. We use X-ray source catalogues from eROSITA, XMM-Newton, Chandra, and ROSAT to derive X-ray luminosities of exoplanet host stars in the 0.2–2 keV energy band with an underlying coronal, that is, optically thin thermal spectrum. We present a catalogue of stellar X-ray and EUV luminosities, exoplanetary X-ray and EUV irradiation fluxes, and estimated mass-loss rates for a total of 287 exoplanets, 96 of which are characterised for the first time based on new eROSITA detections. We identify 14 first-time X-ray detections of transiting exoplanets that are subject to irradiation levels known to cause observable evaporation signatures in other exoplanets. This makes them suitable targets for follow-up observations.
KW - stars: coronae
KW - stars: activity
KW - planet-star interactions
KW - planets and
KW - satellites: atmospheres
KW - X-rays: stars
Y1 - 2022
U6 - https://doi.org/10.1051/0004-6361/202141097
SN - 0004-6361
SN - 1432-0746
VL - 661
PB - EDP Sciences
CY - Les Ulis
ER -
TY - JOUR
A1 - Ye, Fangyuan
A1 - Zhang, Shuo
A1 - Warby, Jonathan
A1 - Wu, Jiawei
A1 - Gutierrez-Partida, Emilio
A1 - Lang, Felix
A1 - Shah, Sahil
A1 - Saglamkaya, Elifnaz
A1 - Sun, Bowen
A1 - Zu, Fengshuo
A1 - Shoai, Safa
A1 - Wang, Haifeng
A1 - Stiller, Burkhard
A1 - Neher, Dieter
A1 - Zhu, Wei-Hong
A1 - Stolterfoht, Martin
A1 - Wu, Yongzhen
T1 - Overcoming C₆₀-induced interfacial recombination in inverted perovskite solar cells by electron-transporting carborane
JF - Nature Communications
N2 - Inverted perovskite solar cells still suffer from significant non-radiative recombination losses at the perovskite surface and across the perovskite/C₆₀ interface, limiting the future development of perovskite-based single- and multi-junction photovoltaics. Therefore, more effective inter- or transport layers are urgently required. To tackle these recombination losses, we introduce ortho-carborane as an interlayer material that has a spherical molecular structure and a three-dimensional aromaticity. Based on a variety of experimental techniques, we show that ortho-carborane decorated with phenylamino groups effectively passivates the perovskite surface and essentially eliminates the non-radiative recombination loss across the perovskite/C₆₀ interface with high thermal stability. We further demonstrate the potential of carborane as an electron transport material, facilitating electron extraction while blocking holes from the interface. The resulting inverted perovskite solar cells deliver a power conversion efficiency of over 23% with a low non-radiative voltage loss of 110 mV, and retain >97% of the initial efficiency after 400 h of maximum power point tracking. Overall, the designed carborane based interlayer simultaneously enables passivation, electron-transport and hole-blocking and paves the way toward more efficient and stable perovskite solar cells.
Y1 - 2022
U6 - https://doi.org/10.1038/s41467-022-34203-x
SN - 2041-1723
VL - 13
IS - 1
PB - Springer Nature
CY - London
ER -
TY - JOUR
A1 - Omel'chenko, Oleh
A1 - Ocampo-Espindola, Jorge Luis
A1 - Kiss, István Z.
T1 - Asymmetry-induced isolated fully synchronized state in coupled oscillator populations
JF - Physical review : E, Statistical, nonlinear and soft matter physics
N2 - A symmetry-breaking mechanism is investigated that creates bistability between fully and partially synchronized states in oscillator networks. Two populations of oscillators with unimodal frequency distribution and different amplitudes, in the presence of weak global coupling, are shown to simplify to a modular network with asymmetrical coupling. With increasing the coupling strength, a synchronization transition is observed with an isolated fully synchronized state. The results are interpreted theoretically in the thermodynamic limit and confirmed in experiments with chemical oscillators.
Y1 - 2021
U6 - https://doi.org/10.1103/PhysRevE.104.L022202
SN - 2470-0045
SN - 2470-0053
VL - 104
IS - 2
PB - American Physical Society
CY - Melville, NY
ER -
TY - JOUR
A1 - Meyer, Dominique M.-A.
A1 - Pohl, Martin
A1 - Petrov, Miroslav
A1 - Egberts, Kathrin
T1 - Mixing of materials in magnetized core-collapse supernova remnants
JF - Monthly notices of the Royal Astronomical Society
N2 - Core-collapse supernova remnants are structures of the interstellar medium (ISM) left behind the explosive death of most massive stars ( ?40 M-?). Since they result in the expansion of the supernova shock wave into the gaseous environment shaped by the star's wind history, their morphology constitutes an insight into the past evolution of their progenitor star. Particularly, fast-mo ving massiv e stars can produce asymmetric core-collapse superno va remnants. We inv estigate the mixing of materials in core-collapse supernova remnants generated by a moving massive 35 M-? star, in a magnetized ISM. Stellar rotation and the wind magnetic field are time-dependently included into the models which follow the entire evolution of the stellar surroundings from the zero-age main-sequence to 80 kyr after the supernova explosion. It is found that very little main-sequence material is present in remnants from moving stars, that the Wolf-Rayet wind mixes very efficiently within the 10 kyr after the explosion, while the red supergiant material is still unmixed by 30 per cent within 50 kyr after the supernova. Our results indicate that the faster the stellar motion, the more complex the internal organization of the supernova remnant and the more ef fecti ve the mixing of ejecta therein. In contrast, the mixing of stellar wind material is only weakly affected by progenitor motion, if at all.
KW - ISM : supernova remnants
KW - (magnetohydrodynamics) MHD
KW - stars evolution
KW - stars: massive
Y1 - 2023
U6 - https://doi.org/10.1093/mnras/stad906
SN - 0035-8711
SN - 1365-2966
VL - 521
IS - 4
SP - 5354
EP - 5371
PB - Oxford Univ. Press
CY - Oxford
ER -
TY - JOUR
A1 - Davidsen, Joern
A1 - Kwiatek, Grzegorz
A1 - Charalampidou, Elli-Maria
A1 - Goebel, Thomas H. W.
A1 - Stanchits, Sergei
A1 - Rueck, Marc
A1 - Dresen, Georg
T1 - Triggering Processes in Rock Fracture
JF - Physical review letters
N2 - We study triggering processes in triaxial compression experiments under a constant displacement rate on sandstone and granite samples using spatially located acoustic emission events and their focal mechanisms. We present strong evidence that event-event triggering plays an important role in the presence of large-scale or macrocopic imperfections, while such triggering is basically absent if no significant imperfections are present. In the former case, we recover all established empirical relations of aftershock seismicity including the Gutenberg-Richter relation, a modified version of the Omori-Utsu relation and the productivity relation-despite the fact that the activity is dominated by compaction-type events and triggering cascades have a swarmlike topology. For the Gutenberg-Richter relations, we find that the b value is smaller for triggered events compared to background events. Moreover, we show that triggered acoustic emission events have a focal mechanism much more similar to their associated trigger than expected by chance.
Y1 - 2017
U6 - https://doi.org/10.1103/PhysRevLett.119.068501
SN - 0031-9007
SN - 1079-7114
VL - 119
PB - American Physical Society
CY - College Park
ER -
TY - JOUR
A1 - Kretzschmar, Mirjam E.
A1 - Ashby, Ben
A1 - Fearon, Elizabeth
A1 - Overton, Christopher E.
A1 - Panovska-Griffiths, Jasmina
A1 - Pellis, Lorenzo
A1 - Quaife, Matthew
A1 - Rozhnova, Ganna
A1 - Scarabel, Francesca
A1 - Stage, Helena B.
A1 - Swallow, Ben
A1 - Thompson, Robin N.
A1 - Tildesley, Michael J.
A1 - Villela, Daniel Campos
T1 - Challenges for modelling interventions for future pandemics
JF - Epidemics
N2 - Mathematical modelling and statistical inference provide a framework to evaluate different non-pharmaceutical and pharmaceutical interventions for the control of epidemics that has been widely used during the COVID-19 pandemic. In this paper, lessons learned from this and previous epidemics are used to highlight the challenges for future pandemic control. We consider the availability and use of data, as well as the need for correct parameterisation and calibration for different model frameworks. We discuss challenges that arise in describing and distinguishing between different interventions, within different modelling structures, and allowing both within and between host dynamics. We also highlight challenges in modelling the health economic and political aspects of interventions. Given the diversity of these challenges, a broad variety of interdisciplinary expertise is needed to address them, combining mathematical knowledge with biological and social insights, and including health economics and communication skills. Addressing these challenges for the future requires strong cross disciplinary collaboration together with close communication between scientists and policy makers.
KW - Mathematical models
KW - Pandemics
KW - Pharmaceutical interventions
KW - Non-pharmaceutical interventions
KW - Policy support
Y1 - 2022
U6 - https://doi.org/10.1016/j.epidem.2022.100546
SN - 1755-4365
SN - 1878-0067
VL - 38
PB - Elsevier
CY - Amsterdam
ER -
TY - THES
A1 - Schlemm, Tanja
T1 - The marine ice cliff instability of the Antarctic ice sheet
T1 - Die marine Eisklippeninstabilität des antarktischen Eisschildes
BT - a theory of mélange-buttressed cliff calving and its application in the Parallel Ice Sheet Model
BT - eine Theorie des Mélange-gebremsten Klippenkalbens und ihre Anwendung im Parallel Ice Sheet Model
N2 - The Antarctic ice sheet is the largest freshwater reservoir worldwide. If it were to melt completely, global sea levels would rise by about 58 m. Calculation of projections of the Antarctic contribution to sea level rise under global warming conditions is an ongoing effort which
yields large ranges in predictions. Among the reasons for this are uncertainties related to the physics of ice sheet modeling. These
uncertainties include two processes that could lead to runaway ice retreat: the Marine Ice Sheet Instability (MISI), which causes rapid grounding line retreat on retrograde bedrock, and the Marine Ice Cliff Instability (MICI), in which tall ice cliffs become unstable and calve off, exposing even taller ice cliffs.
In my thesis, I investigated both marine instabilities (MISI and MICI) using the Parallel Ice Sheet Model (PISM), with a focus on MICI.
N2 - Der antarktische Eisschild ist das größte Süßwasserreservoir der Welt. Würde er vollständig schmelzen, würde der globale Meeresspiegel um etwa 58 m ansteigen. Die Ermittlung von Prognosen über den Beitrag der Antarktis zum Anstieg des Meeresspiegels infolge der globalen Erwärmung ist ein fortlaufender Prozess, der große Unterschiede in den Vorhersagen zur Folge hat. Einer der Gründe dafür sind Ungewissheiten im Zusammenhang mit der Physik der Eisschildmodellierung. Zu diesen Unsicherheiten gehören zwei Prozesse, die zu einem unkontrollierten Eisrückzug führen könnten:
die Marine Ice Sheet Instability (MISI), die zu einem schnellen Rückzug der Grundlinie auf rückläufigem Grundgestein führt, und die Marine Ice Cliff Instability (MICI), bei der hohe Eisklippen instabil werden und abkalben, wodurch noch höhere Eisklippen freigelegt werden.
In meiner Dissertation untersuchte ich beide marinen Instabilitäten (MISI und MICI) mit Hilfe des Parallel Ice Sheet Model (PISM), wobei der Schwerpunkt auf MICI lag.
KW - Antarctica
KW - ice sheet modelling
KW - iceberg calving
KW - Antarktis
KW - Eisschildmodellierung
KW - Eisbergkalbung
Y1 - 2022
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-586333
ER -
TY - THES
A1 - Kuhla, Kilian
T1 - Impact, distribution, and adaptation
T1 - Auswirkung, Verteilung und Anpassung
BT - how weather extremes threaten the economic network
BT - wie Wetterextreme das ökonomische Netzwerk bedrohen
N2 - Weather extremes pose a persistent threat to society on multiple layers. Besides an average of ~37,000 deaths per year, climate-related disasters cause destroyed properties and impaired economic activities, eroding people's livelihoods and prosperity. While global temperature rises – caused by anthropogenic greenhouse gas emissions – the direct impacts of climatic extreme events increase and will further intensify without proper adaptation measures. Additionally, weather extremes do not only have local direct effects. Resulting economic repercussions can propagate either upstream or downstream along trade chains causing indirect effects. One approach to analyze these indirect effects within the complex global supply network is the agent-based model Acclimate. Using and extending this loss-propagation model, I focus in this thesis on three aspects of the relation between weather extremes and economic repercussions.
First, extreme weather events cause direct impacts on local economic performance. I compute daily local direct output loss time series of heat stress, river floods, tropical cyclones, and their consecutive occurrence using (near-future) climate projection ensembles. These regional impacts are estimated based on physical drivers and local productivity distribution. Direct effects of the aforementioned disaster categories are widely heterogeneous concerning regional and temporal distribution. As well, their intensity changes differently under future warming. Focusing on the hurricane-impacted capital, I find that long-term growth losses increase with higher heterogeneity of a shock ensemble.
Second, repercussions are sectorally and regionally distributed via economic ripples within the trading network, causing higher-order effects. I use Acclimate to identify three phases of those economic ripples. Furthermore, I compute indirect impacts and analyze overall regional and global production and consumption changes. Regarding heat stress, global consumer losses double while direct output losses increase by a factor 1.5 between 2000 – 2039. In my research I identify the effect of economic ripple resonance and introduce it to climate impact research. This effect occurs if economic ripples of consecutive disasters overlap, which increases economic responses such as an enhancement of consumption losses. These loss enhancements can even be more amplified with increasing direct output losses, e.g. caused by climate crises.
Transport disruptions can cause economic repercussions as well. For this, I extend the model Acclimate with a geographical transportation route and expand the decision horizon of economic agents. Using this, I show that policy-induced sudden trade restrictions (e.g. a no-deal Brexit) can significantly reduce the longer-term economic prosperity of affected regions. Analyses of transportation disruptions in typhoon seasons indicate that severely affected regions must reduce production as demand falls during a storm. Substituting suppliers may compensate for fluctuations at the beginning of the storm, which fails for prolonged disruptions.
Third, possible coping mechanisms and adaptation strategies arise from direct and indirect economic responses to weather extremes. Analyzing annual trade changes due to typhoon-induced transport disruptions depict that overall exports rise. This trade resilience increases with higher network node diversification. Further, my research shows that a basic insurance scheme may diminish hurricane-induced long-term growth losses due to faster reconstruction in disasters aftermaths. I find that insurance coverage could be an economically reasonable coping scheme towards higher losses caused by the climate crisis. Indirect effects within the global economic network from weather extremes indicate further adaptation possibilities. For one, diversifying linkages reduce the hazard of sharp price increases. Next to this, close economic interconnections with regions that do not share the same extreme weather season can be economically beneficial in the medium run. Furthermore, economic ripple resonance effects should be considered while computing costs. Overall, an increase in local adaptation measures reduces economic ripples within the trade network and possible losses elsewhere. In conclusion, adaptation measures are necessary and potential present, but it seems rather not possible to avoid all direct or indirect losses.
As I show in this thesis, dynamical modeling gives valuable insights into how direct and indirect economic impacts arise from different categories of weather extremes. Further, it highlights the importance of resolving individual extremes and reflecting amplifying effects caused by incomplete recovery or consecutive disasters.
N2 - Wetterextreme stellen für die Gesellschaft eine anhaltende Bedrohung auf mehreren Ebenen dar. Neben durchschnittlich ~37.000 Todesfällen pro Jahr verursachen meteorologische Katastrophen Eigentumsschäden und Wirtschaftsbeeinträchtigungen, wodurch die Lebensgrundlagen und der Wohlstand der Menschen untergraben werden. Während die globale Temperatur – verursacht durch anthropogene Treibhausgasemissionen – ansteigt, nehmen die direkten Auswirkungen klimatischer Extremereignisse zu und werden sich ohne geeignete Anpassungsmaßnahmen weiter verstärken.
Hinzu kommt, dass Wetterextreme nicht nur lokal direkte Schäden anrichten, sondern sich wetterbedingte wirtschaftliche Auswirkungen auch entlang der Handelsketten ausbreiten und so indirekte Effekte nach sich ziehen. Ein Ansatz zur Analyse dieser indirekten Auswirkungen innerhalb des komplexen globalen Versorgungsnetzes ist das agentenbasierte Modell Acclimate.
In meiner Dissertation verwende und erweitere ich dieses Schadenspropagationsmodell, um drei Aspekte der Beziehung zwischen Wetterextremen und wirtschaftlichen Auswirkungen zu untersuchen.
Erstens verursachen extreme Wetterereignisse direkte Schäden in lokaler Wirtschaftsleistung. Die regionalen Auswirkungen werden auf der Grundlage von physikalischen Faktoren und lokalen Produktivitätsverteilungen kalkuliert. Ich berechne tägliche Zeitreihen lokaler Produktionsverluste durch Hitzestress, Überschwemmungen, tropische Wirbelstürme und deren konsekutives Auftreten unter Verwendung von Klimaprojektionsensembles. Die direkten Auswirkungen der oben genannten Katastrophenkategorien sind sehr heterogen in Bezug auf die regionale und zeitliche Verteilung. Ebenso ändert sich ihre Stärke unterschiedlich unter zukünftiger Erwärmung. Meine Forschungsergebnisse zeigen, dass Kapitalstock, welcher von Wirbelstürmen beschädigt ist, langfristige Wachstumsverluste verursacht. Dabei nehmen die Verluste zu, wenn die Heterogenität der Schocks steigt.
Zweitens werden die wetterbedingten Auswirkungen durch wirtschaftliche Wellen innerhalb des Handelsnetzes auf verschiedene Wirtschaftssektoren und Regionen verteilt. In meiner Dissertation, untersuche ich die wirtschaftlichen Wellen mittels Acclimate und mache dabei drei Wellenphasen aus. Darüber hinaus berechne ich indirekte Auswirkungen und analysiere die regionalen und globalen Produktionsveränderungen sowie die Auswirkungen auf Konsumierende. Für letztere verdoppeln sich zwischen 2000 und 2039 die weltweiten Verluste durch Hitzestress, während im selben Zeitraum die direkten Produktionsverluste nur um den Faktor 1.5 steigen. Im Zuge meiner Forschung identifiziere ich den Effekt der ökonomischen Wellenresonanz und führe ihn in die Klimafolgenforschung ein. Dieser Effekt tritt auf, wenn sich die ökonomischen Wellen aufeinanderfolgender Katastrophen überlagern, was wirtschaftliche Reaktionen intensiviert wie beispielsweise eine Steigerung der Konsumverluste. Diese Dynamik der Verluste kann durch zunehmende direkte Produktionsverluste, hervorgerufen etwa durch den Klimawandel, noch verstärkt werden.
Auch Handelsunterbrechungen können wirtschaftliche Auswirkungen haben. Um diese zu berechnen, erweitere ich das Modell Acclimate um ein geografisches Transportnetzwerk und weite den Entscheidungshorizont der Wirtschaftsakteure aus. Politisch bedingte plötzliche Handelsbeschränkungen (z. B. ein No-Deal-Brexit) können den längerfristigen wirtschaftlichen Wohlstand der betroffenen Regionen erheblich verringern. Analysen von Transportunterbrechungen in der Taifunsaison zeigen, dass stark betroffene Regionen ihre Produktionen reduzieren müssen, wenn die Nachfrage während eines Sturms sinkt. Zu Beginn eines Sturms können Handelsschwankungen durch alternative Lieferanten ausgeglichen werden, was jedoch bei längeren Unterbrechungen nicht mehr gelingt.
Drittens ergeben sich mögliche Anpassungsmechanismen und -strategien aus direkten und indirekten wirtschaftlichen Reaktionen auf Wetterextreme. Die Analyse der jährlichen Handelsveränderungen in der Taifunsaison zeigt, dass Exporte insgesamt zunehmen. Diese Widerstandsfähigkeit des Handels wächst mit einer höheren Diversifizierung der Handelspartner. Weiterhin zeigt meine Forschung an Wirtschaftswachstumsmodellen, dass ein Versicherungssystem langfristige Wachstumsverluste, verursacht durch Tropenstürme, durch schnelleren Wiederaufbau verringern kann. Ich komme zu dem Schluss, dass ein Versicherungsschutz eine wirtschaftlich sinnvolle Anpassungsstrategie gegenüber höheren Schäden durch die Klimakrise sein kann. Ebenso weisen indirekte Auswirkungen von Wetterextremen innerhalb des globalen Wirtschaftsnetzes auf weitere Anpassungsmöglichkeiten hin. Zunächst vermindert eine diversifizierte Vernetzung die Gefahr eines starken Preisanstiegs. Ebenso kann eine enge wirtschaftliche Verflechtung von Regionen, die nicht dieselbe Unwettersaison haben, mittelfristig wirtschaftlich vorteilhaft sein. Weiterhin sollten bei der Berechnung der Kosten wirtschaftliche Resonanzeffekte berücksichtigt werden. Eine Verstärkung der lokalen Anpassungsmaßnahmen verringert die Amplitude ökonomischer Wellen und damit auch potentielle Verluste in anderen Regionen. Insgesamt sind Anpassungsmaßnahmen notwendig, aber es scheint trotz dieser nicht möglich zu sein, alle direkten oder indirekten Verluste zu vermeiden.
Wie ich in meiner Arbeit darlege, gibt die dynamische Modellierung wertvolle Einblicke in die Art und Weise, wie direkte und indirekte wirtschaftliche Auswirkungen durch verschiedene Wetterextreme entstehen. Darüber hinaus wird deutlich, wie wichtig es ist, einzelne Extremereignisse aufzulösen und Verstärkungseffekte zu berücksichtigen, die durch unvollständigen Wiederaufbau oder aufeinanderfolgende Katastrophen verursacht werden.
KW - climate change
KW - weather extremes
KW - macro-economic modelling
KW - network theory
KW - economic network
KW - Klimawandel
KW - Wetterextreme
KW - Makroökonomische Modellierung
KW - Netzwerktheorie
KW - Ökonomisches Netzwerk
Y1 - 2022
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-552668
ER -
TY - JOUR
A1 - Seroussi, Helene
A1 - Nowicki, Sophie
A1 - Simon, Erika
A1 - Abe-Ouchi, Ayako
A1 - Albrecht, Torsten
A1 - Brondex, Julien
A1 - Cornford, Stephen
A1 - Dumas, Christophe
A1 - Gillet-Chaulet, Fabien
A1 - Goelzer, Heiko
A1 - Golledge, Nicholas R.
A1 - Gregory, Jonathan M.
A1 - Greve, Ralf
A1 - Hoffman, Matthew J.
A1 - Humbert, Angelika
A1 - Huybrechts, Philippe
A1 - Kleiner, Thomas
A1 - Larourl, Eric
A1 - Leguy, Gunter
A1 - Lipscomb, William H.
A1 - Lowry, Daniel
A1 - Mengel, Matthias
A1 - Morlighem, Mathieu
A1 - Pattyn, Frank
A1 - Payne, Anthony J.
A1 - Pollard, David
A1 - Price, Stephen F.
A1 - Quiquet, Aurelien
A1 - Reerink, Thomas J.
A1 - Reese, Ronja
A1 - Rodehacke, Christian B.
A1 - Schlegel, Nicole-Jeanne
A1 - Shepherd, Andrew
A1 - Sun, Sainan
A1 - Sutter, Johannes
A1 - Van Breedam, Jonas
A1 - van de Wal, Roderik S. W.
A1 - Winkelmann, Ricarda
A1 - Zhang, Tong
T1 - initMIP-Antarctica
BT - an ice sheet model initialization experiment of ISMIP6
JF - The Cryosphere : TC ; an interactive open access journal of the European Geosciences Union
N2 - Ice sheet numerical modeling is an important tool to estimate the dynamic contribution of the Antarctic ice sheet to sea level rise over the coming centuries. The influence of initial conditions on ice sheet model simulations, however, is still unclear. To better understand this influence, an initial state intercomparison exercise (initMIP) has been developed to compare, evaluate, and improve initialization procedures and estimate their impact on century-scale simulations. initMlP is the first set of experiments of the Ice Sheet Model Intercomparison Project for CMIP6 (ISMIP6), which is the primary Coupled Model Intercomparison Project Phase 6 (CMIP6) activity focusing on the Greenland and Antarctic ice sheets. Following initMlP-Greenland, initMlP-Antarctica has been designed to explore uncertainties associated with model initialization and spin-up and to evaluate the impact of changes in external forcings. Starting from the state of the Antarctic ice sheet at the end of the initialization procedure, three forward experiments are each run for 100 years: a control run, a run with a surface mass balance anomaly, and a run with a basal melting anomaly beneath floating ice. This study presents the results of initMlP-Antarctica from 25 simulations performed by 16 international modeling groups. The submitted results use different initial conditions and initialization methods, as well as ice flow model parameters and reference external forcings. We find a good agreement among model responses to the surface mass balance anomaly but large variations in responses to the basal melting anomaly. These variations can be attributed to differences in the extent of ice shelves and their upstream tributaries, the numerical treatment of grounding line, and the initial ocean conditions applied, suggesting that ongoing efforts to better represent ice shelves in continental-scale models should continue.
Y1 - 2019
U6 - https://doi.org/10.5194/tc-13-1441-2019
SN - 1994-0416
SN - 1994-0424
VL - 13
IS - 5
SP - 1441
EP - 1471
PB - Copernicus
CY - Göttingen
ER -
TY - JOUR
A1 - Reese, Ronja
A1 - Albrecht, Torsten
A1 - Mengel, Matthias
A1 - Asay-Davis, Xylar
A1 - Winkelmann, Ricarda
T1 - Antarctic sub-shelf melt rates via PICO
JF - The Cryosphere : TC ; an interactive open access journal of the European Geosciences Union
N2 - Ocean-induced melting below ice shelves is one of the dominant drivers for mass loss from the Antarctic Ice Sheet at present. An appropriate representation of sub-shelf melt rates is therefore essential for model simulations of marine-based ice sheet evolution. Continental-scale ice sheet models often rely on simple melt-parameterizations, in particular for long-term simulations, when fully coupled ice-ocean interaction becomes computationally too expensive. Such parameterizations can account for the influence of the local depth of the ice-shelf draft or its slope on melting. However, they do not capture the effect of ocean circulation underneath the ice shelf. Here we present the Potsdam Ice-shelf Cavity mOdel (PICO), which simulates the vertical overturning circulation in ice-shelf cavities and thus enables the computation of sub-shelf melt rates consistent with this circulation. PICO is based on an ocean box model that coarsely resolves ice shelf cavities and uses a boundary layer melt formulation. We implement it as a module of the Parallel Ice Sheet Model (PISM) and evaluate its performance under present-day conditions of the Southern Ocean. We identify a set of parameters that yield two-dimensional melt rate fields that qualitatively reproduce the typical pattern of comparably high melting near the grounding line and lower melting or refreezing towards the calving front. PICO captures the wide range of melt rates observed for Antarctic ice shelves, with an average of about 0.1 ma(-1) for cold sub-shelf cavities, for example, underneath Ross or Ronne ice shelves, to 16 ma(-1) for warm cavities such as in the Amundsen Sea region. This makes PICO a computationally feasible and more physical alternative to melt parameterizations purely based on ice draft geometry.
Y1 - 2018
U6 - https://doi.org/10.5194/tc-12-1969-2018
SN - 1994-0416
SN - 1994-0424
VL - 12
IS - 6
SP - 1969
EP - 1985
PB - Copernicus
CY - Göttingen
ER -
TY - JOUR
A1 - Levermann, Anders
A1 - Winkelmann, Ricarda
A1 - Nowicki, S.
A1 - Fastook, J. L.
A1 - Frieler, Katja
A1 - Greve, R.
A1 - Hellmer, H. H.
A1 - Martin, M. A.
A1 - Meinshausen, Malte
A1 - Mengel, Matthias
A1 - Payne, A. J.
A1 - Pollard, D.
A1 - Sato, T.
A1 - Timmermann, R.
A1 - Wang, Wei Li
A1 - Bindschadler, Robert A.
T1 - Projecting antarctic ice discharge using response functions from SeaRISE ice-sheet models
JF - Earth system dynamics
N2 - The largest uncertainty in projections of future sea-level change results from the potentially changing dynamical ice discharge from Antarctica. Basal ice-shelf melting induced by a warming ocean has been identified as a major cause for additional ice flow across the grounding line. Here we attempt to estimate the uncertainty range of future ice discharge from Antarctica by combining uncertainty in the climatic forcing, the oceanic response and the ice-sheet model response. The uncertainty in the global mean temperature increase is obtained from historically constrained emulations with the MAGICC-6.0 (Model for the Assessment of Greenhouse gas Induced Climate Change) model. The oceanic forcing is derived from scaling of the subsurface with the atmospheric warming from 19 comprehensive climate models of the Coupled Model Intercomparison Project (CMIP-5) and two ocean models from the EU-project Ice2Sea. The dynamic ice-sheet response is derived from linear response functions for basal ice-shelf melting for four different Antarctic drainage regions using experiments from the Sea-level Response to Ice Sheet Evolution (SeaRISE) intercomparison project with five different Antarctic ice-sheet models. The resulting uncertainty range for the historic Antarctic contribution to global sea-level rise from 1992 to 2011 agrees with the observed contribution for this period if we use the three ice-sheet models with an explicit representation of ice-shelf dynamics and account for the time-delayed warming of the oceanic subsurface compared to the surface air temperature. The median of the additional ice loss for the 21st century is computed to 0.07 m (66% range: 0.02-0.14 m; 90% range: 0.0-0.23 m) of global sea-level equivalent for the low-emission RCP-2.6 (Representative Concentration Pathway) scenario and 0.09 m (66% range: 0.04-0.21 m; 90% range: 0.01-0.37 m) for the strongest RCP-8.5. Assuming no time delay between the atmospheric warming and the oceanic subsurface, these values increase to 0.09 m (66% range: 0.04-0.17 m; 90% range: 0.02-0.25 m) for RCP-2.6 and 0.15 m (66% range: 0.07-0.28 m; 90% range: 0.04-0.43 m) for RCP-8.5. All probability distributions are highly skewed towards high values. The applied ice-sheet models are coarse resolution with limitations in the representation of grounding-line motion. Within the constraints of the applied methods, the uncertainty induced from different ice-sheet models is smaller than that induced by the external forcing to the ice sheets.
Y1 - 2014
U6 - https://doi.org/10.5194/esd-5-271-2014
SN - 2190-4979
SN - 2190-4987
VL - 5
IS - 2
SP - 271
EP - 293
PB - Copernicus
CY - Göttingen
ER -
TY - JOUR
A1 - Steffen, Will
A1 - Röckstrom, Johan
A1 - Richardson, Katherine
A1 - Lenton, Timothy M.
A1 - Folke, Carl
A1 - Liverman, Diana
A1 - Summerhayes, Colin P.
A1 - Barnosky, Anthony D.
A1 - Cornell, Sarah E.
A1 - Crucifix, Michel
A1 - Donges, Jonathan
A1 - Fetzer, Ingo
A1 - Lade, Steven J.
A1 - Scheffer, Marten
A1 - Winkelmann, Ricarda
A1 - Schellnhuber, Hans Joachim
T1 - Trajectories of the Earth System in the Anthropocene
JF - Proceedings of the National Academy of Sciences of the United States of America
N2 - We explore the risk that self-reinforcing feedbacks could push the Earth System toward a planetary threshold that, if crossed, could prevent stabilization of the climate at intermediate temperature rises and cause continued warming on a "Hothouse Earth" pathway even as human emissions are reduced. Crossing the threshold would lead to a much higher global average temperature than any interglacial in the past 1.2 million years and to sea levels significantly higher than at any time in the Holocene. We examine the evidence that such a threshold might exist and where it might be. If the threshold is crossed, the resulting trajectory would likely cause serious disruptions to ecosystems, society, and economies. Collective human action is required to steer the Earth System away from a potential threshold and stabilize it in a habitable interglacial-like state. Such action entails stewardship of the entire Earth System-biosphere, climate, and societies-and could include decarbonization of the global economy, enhancement of biosphere carbon sinks, behavioral changes, technological innovations, new governance arrangements, and transformed social values.
KW - Earth System trajectories
KW - climate change
KW - Anthropocene
KW - biosphere feedbacks
KW - tipping elements
Y1 - 2018
U6 - https://doi.org/10.1073/pnas.1810141115
SN - 0027-8424
VL - 115
IS - 33
SP - 8252
EP - 8259
PB - National Acad. of Sciences
CY - Washington
ER -
TY - JOUR
A1 - Clark, Peter U.
A1 - Shakun, Jeremy D.
A1 - Marcott, Shaun A.
A1 - Mix, Alan C.
A1 - Eby, Michael
A1 - Kulp, Scott
A1 - Levermann, Anders
A1 - Milne, Glenn A.
A1 - Pfister, Patrik L.
A1 - Santer, Benjamin D.
A1 - Schrag, Daniel P.
A1 - Solomon, Susan
A1 - Stocker, Thomas F.
A1 - Strauss, Benjamin H.
A1 - Weaver, Andrew J.
A1 - Winkelmann, Ricarda
A1 - Archer, David
A1 - Bard, Edouard
A1 - Goldner, Aaron
A1 - Lambeck, Kurt
A1 - Pierrehumbert, Raymond T.
A1 - Plattner, Gian-Kasper
T1 - Consequences of twenty-first-century policy for multi-millennial climate
and sea-level change
JF - Nature climate change
N2 - Most of the policy debate surrounding the actions needed to mitigate and adapt to anthropogenic climate change has been framed by observations of the past 150 years as well as climate and sea-level projections for the twenty-first century. The focus on this 250-year window, however, obscures some of the most profound problems associated with climate change. Here, we argue that the twentieth and twenty-first centuries, a period during which the overwhelming majority of human-caused carbon emissions are likely to occur, need to be placed into a long-term context that includes the past 20 millennia, when the last Ice Age ended and human civilization developed, and the next ten millennia, over which time the projected impacts of anthropogenic climate change will grow and persist. This long-term perspective illustrates that policy decisions made in the next few years to decades will have profound impacts on global climate, ecosystems and human societies - not just for this century, but for the next ten millennia and beyond.
Y1 - 2016
U6 - https://doi.org/10.1038/NCLIMATE2923
SN - 1758-678X
SN - 1758-6798
VL - 6
SP - 360
EP - 369
PB - Nature Publ. Group
CY - London
ER -
TY - JOUR
A1 - Ciemer, Catrin
A1 - Boers, Niklas
A1 - Hirota, Marina
A1 - Kurths, Jürgen
A1 - Müller-Hansen, Finn
A1 - Oliveira, Rafael S.
A1 - Winkelmann, Ricarda
T1 - Higher resilience to climatic disturbances in tropical vegetation exposed to more variable rainfall
JF - Nature geoscience
N2 - With ongoing global warming, the amount and frequency of precipitation in the tropics is projected to change substantially. While it has been shown that tropical forests and savannahs are sustained within the same intermediate mean annual precipitation range, the mechanisms that lead to the resilience of these ecosystems are still not fully understood. In particular, the long-term impact of rainfall variability on resilience is as yet unclear. Here we present observational evidence that both tropical forest and savannah exposed to a higher rainfall variability-in particular on interannual scales-during their long-term past are overall more resilient against climatic disturbances. Based on precipitation and tree cover data in the Brazilian Amazon basin, we constructed potential landscapes that enable us to systematically measure the resilience of the different ecosystems. Additionally, we infer that shifts from forest to savannah due to decreasing precipitation in the future are more likely to occur in regions with a precursory lower rainfall variability. Long-term rainfall variability thus needs to be taken into account in resilience analyses and projections of vegetation response to climate change.
Y1 - 2019
U6 - https://doi.org/10.1038/s41561-019-0312-z
SN - 1752-0894
SN - 1752-0908
VL - 12
IS - 3
SP - 174
EP - 179
PB - Nature Publ. Group
CY - New York
ER -
TY - JOUR
A1 - Ganopolski, A.
A1 - Winkelmann, Ricarda
A1 - Schellnhuber, Hans Joachim
T1 - Critical insolation-CO2 relation for diagnosing past and future glacial inception
JF - Nature : the international weekly journal of science
N2 - The past rapid growth of Northern Hemisphere continental ice sheets, which terminated warm and stable climate periods, is generally attributed to reduced summer insolation in boreal latitudes(1-3). Yet such summer insolation is near to its minimum at present(4), and there are no signs of a new ice age(5). This challenges our understanding of the mechanisms driving glacial cycles and our ability to predict the next glacial inception(6). Here we propose a critical functional relationship between boreal summer insolation and global carbon dioxide (CO2) concentration, which explains the beginning of the past eight glacial cycles and might anticipate future periods of glacial inception. Using an ensemble of simulations generated by an Earth system model of intermediate complexity constrained by palaeoclimatic data, we suggest that glacial inception was narrowly missed before the beginning of the Industrial Revolution. The missed inception can be accounted for by the combined effect of relatively high late-Holocene CO2 concentrations and the low orbital eccentricity of the Earth(7). Additionally, our analysis suggests that even in the absence of human perturbations no substantial build-up of ice sheets would occur within the next several thousand years and that the current interglacial would probably last for another 50,000 years. However, moderate anthropogenic cumulative CO2 emissions of 1,000 to 1,500 gigatonnes of carbon will postpone the next glacial inception by at least 100,000 years(8,9). Our simulations demonstrate that under natural conditions alone the Earth system would be expected to remain in the present delicately balanced interglacial climate state, steering clear of both large-scale glaciation of the Northern Hemisphere and its complete deglaciation, for an unusually long time.
Y1 - 2016
U6 - https://doi.org/10.1038/nature16494
SN - 0028-0836
SN - 1476-4687
VL - 529
SP - 200
EP - U159
PB - Nature Publ. Group
CY - London
ER -
TY - JOUR
A1 - Reese, Ronja
A1 - Winkelmann, Ricarda
A1 - Gudmundsson, Gudmundur Hilmar
T1 - Grounding-line flux formula applied as a flux condition in numerical simulations fails for buttressed Antarctic ice streams
JF - The Cryosphere : TC ; an interactive open access journal of the European Geosciences Union
N2 - Currently, several large-scale ice-flow models impose a condition on ice flux across grounding lines using an analytically motivated parameterisation of grounding-line flux. It has been suggested that employing this analytical expression alleviates the need for highly resolved computational domains around grounding lines of marine ice sheets. While the analytical flux formula is expected to be accurate in an unbuttressed flow-line setting, its validity has hitherto not been assessed for complex and realistic geometries such as those of the Antarctic Ice Sheet. Here the accuracy of this analytical flux formula is tested against an optimised ice flow model that uses a highly resolved computational mesh around the Antarctic grounding lines. We find that when applied to the Antarctic Ice Sheet the analytical expression provides inaccurate estimates of ice fluxes for almost all grounding lines. Furthermore, in many instances direct application of the analytical formula gives rise to unphysical complex-valued ice fluxes. We conclude that grounding lines of the Antarctic Ice Sheet are, in general, too highly buttressed for the analytical parameterisation to be of practical value for the calculation of grounding-line fluxes.
Y1 - 2018
U6 - https://doi.org/10.5194/tc-12-3229-2018
SN - 1994-0416
SN - 1994-0424
VL - 12
IS - 10
SP - 3229
EP - 3242
PB - Copernicus
CY - Göttingen
ER -
TY - JOUR
A1 - Ciemer, Catrin
A1 - Rehm, Lars
A1 - Kurths, Jürgen
A1 - Donner, Reik Volker
A1 - Winkelmann, Ricarda
A1 - Boers, Niklas
T1 - An early-warning indicator for Amazon droughts exclusively based on tropical Atlantic sea surface temperatures
JF - Environmental Research Letters
N2 - Droughts in tropical South America have an imminent and severe impact on the Amazon rainforest and affect the livelihoods of millions of people. Extremely dry conditions in Amazonia have been previously linked to sea surface temperature (SST) anomalies in the adjacent tropical oceans. Although the sources and impacts of such droughts have been widely studied, establishing reliable multi-year lead statistical forecasts of their occurrence is still an ongoing challenge. Here, we further investigate the relationship between SST and rainfall anomalies using a complex network approach. We identify four ocean regions which exhibit the strongest overall SST correlations with central Amazon rainfall, including two particularly prominent regions in the northern and southern tropical Atlantic. Based on the time-dependent correlation between SST anomalies in these two regions alone, we establish a new early-warning method for droughts in the central Amazon basin and demonstrate its robustness in hindcasting past major drought events with lead-times up to 18 months.
KW - complex networks
KW - droughts
KW - prediction
KW - Amazon rainforest
Y1 - 2019
VL - 15
IS - 9
PB - IOP - Institute of Physics Publishing
CY - Bristol
ER -
TY - JOUR
A1 - Frieler, Katja
A1 - Clark, Peter U.
A1 - He, Feng
A1 - Buizert, Christo
A1 - Reese, Ronja
A1 - Ligtenberg, Stefan R. M.
A1 - van den Broeke, Michiel R.
A1 - Winkelmann, Ricarda
A1 - Levermann, Anders
T1 - Consistent evidence of increasing Antarctic accumulation with warming
JF - Nature climate change
N2 - Projections of changes in Antarctic Ice Sheet (AIS) surface mass balance indicate a negative contribution to sea level because of the expected increase in precipitation due to the higher moisture holding capacity of warmer air(1). Observations over the past decades, however, are unable to constrain the relation between temperature and accumulation changes because both are dominated by strong natural variability(2-5). Here we derive a consistent continental-scale increase in accumulation of approximately 5 +/- 1% K-1, through the assessment of ice-core data (spanning the large temperature change during the last deglaciation, 21,000 to 10,000 years ago), in combination with palaeo-simulations, future projections by 35 general circulation models (GCMs), and one high-resolution future simulation. The ice-core data and modelling results for the last deglaciation agree, showing uniform local sensitivities of similar to 6% K-1. The palaeo-simulation allows for a continental-scale aggregation of accumulation changes reaching 4.3% K-1. Despite the different timescales, these sensitivities agree with the multi-model mean of 6.1 +/- 2.6% K-1 (GCMprojections) and the continental-scale sensitivity of 4.9% K-1 (high-resolution future simulation). Because some of the mass gain of the AIS is offset by dynamical losses induced by accumulation(6,7), we provide a response function allowing projections of sea-level fall in terms of continental-scale accumulation changes that compete with surface melting and dynamical losses induced by other mechanisms(6,8,9).
Y1 - 2015
U6 - https://doi.org/10.1038/nclimate2574
SN - 1758-678X
SN - 1758-6798
VL - 5
IS - 4
SP - 348
EP - 352
PB - Nature Publ. Group
CY - London
ER -
TY - JOUR
A1 - Levermann, Anders
A1 - Winkelmann, Ricarda
T1 - A simple equation for the melt elevation feedback of ice sheets
JF - The Cryosphere : TC ; an interactive open access journal of the European Geosciences Union
N2 - In recent decades, the Greenland Ice Sheet has been losing mass and has thereby contributed to global sea-level rise. The rate of ice loss is highly relevant for coastal protection worldwide. The ice loss is likely to increase under future warming. Beyond a critical temperature threshold, a meltdown of the Greenland Ice Sheet is induced by the self-enforcing feedback between its lowering surface elevation and its increasing surface mass loss: the more ice that is lost, the lower the ice surface and the warmer the surface air temperature, which fosters further melting and ice loss. The computation of this rate so far relies on complex numerical models which are the appropriate tools for capturing the complexity of the problem. By contrast we aim here at gaining a conceptual understanding by deriving a purposefully simple equation for the self-enforcing feedback which is then used to estimate the melt time for different levels of warming using three observable characteristics of the ice sheet itself and its surroundings. The analysis is purely conceptual in nature. It is missing important processes like ice dynamics for it to be useful for applications to sea-level rise on centennial timescales, but if the volume loss is dominated by the feedback, the resulting logarithmic equation unifies existing numerical simulations and shows that the melt time depends strongly on the level of warming with a critical slow-down near the threshold: the median time to lose 10% of the present-day ice volume varies between about 3500 years for a temperature level of 0.5 degrees C above the threshold and 500 years for 5 degrees C. Unless future observations show a significantly higher melting sensitivity than currently observed, a complete meltdown is unlikely within the next 2000 years without significant ice-dynamical contributions.
Y1 - 2016
U6 - https://doi.org/10.5194/tc-10-1799-2016
SN - 1994-0416
SN - 1994-0424
VL - 10
SP - 1799
EP - 1807
PB - Copernicus
CY - Göttingen
ER -
TY - JOUR
A1 - Winkelmann, Ricarda
A1 - Martin, Maria A.
A1 - Haseloff, Monika
A1 - Albrecht, Torsten
A1 - Bueler, Ed
A1 - Khroulev, C.
A1 - Levermann, Anders
T1 - The Potsdam parallel ice sheet model (PISM-PIK) - Part 1: Model description
JF - The Cryosphere : TC ; an interactive open access journal of the European Geosciences Union
N2 - We present the Potsdam Parallel Ice Sheet Model (PISM-PIK), developed at the Potsdam Institute for Climate Impact Research to be used for simulations of large-scale ice sheet-shelf systems. It is derived from the Parallel Ice Sheet Model (Bueler and Brown, 2009). Velocities are calculated by superposition of two shallow stress balance approximations within the entire ice covered region: the shallow ice approximation (SIA) is dominant in grounded regions and accounts for shear deformation parallel to the geoid. The plug-flow type shallow shelf approximation (SSA) dominates the velocity field in ice shelf regions and serves as a basal sliding velocity in grounded regions. Ice streams can be identified diagnostically as regions with a significant contribution of membrane stresses to the local momentum balance. All lateral boundaries in PISM-PIK are free to evolve, including the grounding line and ice fronts. Ice shelf margins in particular are modeled using Neumann boundary conditions for the SSA equations, reflecting a hydrostatic stress imbalance along the vertical calving face. The ice front position is modeled using a subgrid-scale representation of calving front motion (Albrecht et al., 2011) and a physically-motivated calving law based on horizontal spreading rates. The model is tested in experiments from the Marine Ice Sheet Model Intercomparison Project (MISMIP). A dynamic equilibrium simulation of Antarctica under present-day conditions is presented in Martin et al. (2011).
Y1 - 2011
U6 - https://doi.org/10.5194/tc-5-715-2011
SN - 1994-0416
VL - 5
IS - 3
SP - 715
EP - 726
PB - Copernicus
CY - Göttingen
ER -
TY - JOUR
A1 - Martin, Maria A.
A1 - Winkelmann, Ricarda
A1 - Haseloff, M.
A1 - Albrecht, Tanja
A1 - Bueler, Ed
A1 - Khroulev, C.
A1 - Levermann, Anders
T1 - The Potsdam parallel ice sheet model (PISM-PIK) - Part 2: Dynamic equilibrium simulation of the Antarctic ice sheet
JF - The Cryosphere : TC ; an interactive open access journal of the European Geosciences Union
N2 - We present a dynamic equilibrium simulation of the ice sheet-shelf system on Antarctica with the Potsdam Parallel Ice Sheet Model (PISM-PIK). The simulation is initialized with present-day conditions for bed topography and ice thickness and then run to steady state with constant present-day surface mass balance. Surface temperature and sub-shelf basal melt distribution are parameterized. Grounding lines and calving fronts are free to evolve, and their modeled equilibrium state is compared to observational data. A physically-motivated calving law based on horizontal spreading rates allows for realistic calving fronts for various types of shelves. Steady-state dynamics including surface velocity and ice flux are analyzed for whole Antarctica and the Ronne-Filchner and Ross ice shelf areas in particular. The results show that the different flow regimes in sheet and shelves, and the transition zone between them, are captured reasonably well, supporting the approach of superposition of SIA and SSA for the representation of fast motion of grounded ice. This approach also leads to a natural emergence of sliding-dominated flow in stream-like features in this new 3-D marine ice sheet model.
Y1 - 2011
U6 - https://doi.org/10.5194/tc-5-727-2011
SN - 1994-0416
VL - 5
IS - 3
SP - 727
EP - 740
PB - Copernicus
CY - Göttingen
ER -
TY - THES
A1 - Reese, Ronja
T1 - The far reach of ice-shelf thinning in Antarctica
Y1 - 2018
ER -
TY - THES
A1 - Winkelmann, Ricarda
T1 - The future sea-level contribution from antartica: projections of solid ice discharge
Y1 - 2012
CY - Potsdam
ER -
TY - THES
A1 - Wunderling, Nico
T1 - Nichtlineare Dynamiken und Interaktionen von Kippelementen im Erdsystem
T1 - Nonlinear dynamics and interactions of tipping elements in the Earth system
N2 - With ongoing anthropogenic global warming, some of the most vulnerable components of the Earth system might become unstable and undergo a critical transition. These subsystems are the so-called tipping elements. They are believed to exhibit threshold behaviour and would, if triggered, result in severe consequences for the biosphere and human societies. Furthermore, it has been shown that climate tipping elements are not isolated entities, but interact across the entire Earth system. Therefore, this thesis aims at mapping out the potential for tipping events and feedbacks in the Earth system mainly by the use of complex dynamical systems and network science approaches, but partially also by more detailed process-based models of the Earth system.
In the first part of this thesis, the theoretical foundations are laid by the investigation of networks of interacting tipping elements. For this purpose, the conditions for the emergence of global cascades are analysed against the structure of paradigmatic network types such as Erdös-Rényi, Barabási-Albert, Watts-Strogatz and explicitly spatially embedded networks. Furthermore, micro-scale structures are detected that are decisive for the transition of local to global cascades. These so-called motifs link the micro- to the macro-scale in the network of tipping elements. Alongside a model description paper, all these results are entered into the Python software package PyCascades, which is publicly available on github.
In the second part of this dissertation, the tipping element framework is first applied to components of the Earth system such as the cryosphere and to parts of the biosphere. Afterwards it is applied to a set of interacting climate tipping elements on a global scale. Using the Earth system Model of Intermediate Complexity (EMIC) CLIMBER-2, the temperature feedbacks are quantified, which would arise if some of the large cryosphere elements disintegrate over a long span of time. The cryosphere components that are investigated are the Arctic summer sea ice, the mountain glaciers, the Greenland and the West Antarctic Ice Sheets. The committed temperature increase, in case the ice masses disintegrate, is on the order of an additional half a degree on a global average (0.39-0.46 °C), while local to regional additional temperature increases can exceed 5 °C. This means that, once tipping has begun, additional reinforcing feedbacks are able to increase global warming and with that the risk of further tipping events.
This is also the case in the Amazon rainforest, whose parts are dependent on each other via the so-called moisture-recycling feedback. In this thesis, the importance of drought-induced tipping events in the Amazon rainforest is investigated in detail. Despite the Amazon rainforest is assumed to be adapted to past environmental conditions, it is found that tipping events sharply increase if the drought conditions become too intense in a too short amount of time, outpacing the adaptive capacity of the Amazon rainforest. In these cases, the frequency of tipping cascades also increases to 50% (or above) of all tipping events. In the model that was developed in this study, the southeastern region of the Amazon basin is hit hardest by the simulated drought patterns. This is also the region that already nowadays suffers a lot from extensive human-induced changes due to large-scale deforestation, cattle ranching or infrastructure projects.
Moreover, on the larger Earth system wide scale, a network of conceptualised climate tipping elements is constructed in this dissertation making use of a large literature review, expert knowledge and topological properties of the tipping elements. In global warming scenarios, tipping cascades are detected even under modest scenarios of climate change, limiting global warming to 2 °C above pre-industrial levels. In addition, the structural roles of the climate tipping elements in the network are revealed. While the large ice sheets on Greenland and Antarctica are the initiators of tipping cascades, the Atlantic Meridional Overturning Circulation (AMOC) acts as the transmitter of cascades. Furthermore, in our conceptual climate tipping element model, it is found that the ice sheets are of particular importance for the stability of the entire system of investigated climate tipping elements.
In the last part of this thesis, the results from the temperature feedback study with the EMIC CLIMBER-2 are combined with the conceptual model of climate tipping elements. There, it is observed that the likelihood of further tipping events slightly increases due to the temperature feedbacks even if no further CO$_2$ would be added to the atmosphere.
Although the developed network model is of conceptual nature, it is possible with this work for the first time to quantify the risk of tipping events between interacting components of the Earth system under global warming scenarios, by allowing for dynamic temperature feedbacks at the same time.
N2 - Bei fortdauerndem anthropogenem Klimawandel, könnten einige der vulnerabelsten Komponenten des Erdsystem instabil werden und in einen anderen Zustand übergehen. Diese Komponenten des Erdsystems sind die sogenannten Kippelemente. Bei ihnen wird angenommen, dass sie einen Kipppunkt besitzen ab dem sie in einen qualitativ anderen Zustand übergehen können. Sollte das passieren, hätte das schwerwiegende Konsequenzen für die Biosphäre und menschliche Gesellschaften. Des Weiteren ist gezeigt worden, dass Kippelemente keine isolierte Reigionen oder Prozesse sind, sondern über das gesamte Erdsystem hinweg interagieren. Das Ziel dieser Arbeit ist es daher, die Wahrscheinlichkeit für Kippereignisse sowie deren Feedbacks im Erdsystem zu quantifizieren. Zu diesem Zweck kommen vor allem Frameworks aus der Wissenschaft komplexer Systeme und Netzwerke zum Einsatz. Für einige Teilaspekte dieser Arbeit wird aber auch ein detaillierteres und prozessbasierteres Erdsystemmodell verwendet.
Im ersten Teil dieser Arbeit werden die theoretischen Grundlagen gelegt, indem komplexe Netzwerke bestehend aus interagierenden Kippelementen untersucht werden. Hier werden Voraussetzungen für das Auftreten globaler Kippkaskaden anhand der Struktur paradigmatischer Netzwerktypen analysiert. Diese Typen sind Netzwerke wie Erdös-Rényi, Barabási-Albert, Watts-Strogatz Netzwerke oder auch explizit räumlich eingebettete Netzwerke. Darüber hinaus sind bestimmte Mikrostrukturen in Netzwerken dafür entscheidend, ob sich eine lokale Kaskaden auf das globale Netzwerk ausbreiten kann. Diese Strukturen sind das Bindeglied zwischen der Mikro- und der Makroebene des Netzwerks und werden Motive genannt. Zusammen mit einer Publikation zur Modellbeschreibung, werden alle diese Ergebnisse im Python-Softwarepaket PyCascades veröffentlicht, das auf github öffentlich verfügbar ist.
Im zweiten Teil dieser Dissertation wird das Kippelementframework zunächst auf Kompenenten des Erdsystems angewendet wie der Kryosphäre und Teilen der Biosphäre, und danach auf globaler Skala für interagierende Klimakippelemente. In einem ersten Schritt werden mit dem Erdsystemmodell mittlerer Komplexität CLIMBER-2 die Temperaturfeedbacks ermittelt, die entstehen würden, wenn große Gebiete der Kryosphäre auf lange Sicht eisfrei werden. In dieser Berechnung werden das arktische Sommermeereis, die Gebirgsgletscher, der grönländische und der westantarktische Eisschild berücksichtigt. Die quantifizierte Temperaturerhöhung liegt in der Größenordnung von einem halben Grad zusätzlicher globaler Erwärmung (0.39--0.46°C). Lokale bis regionale Temperaturerhöhungen können allerdings 5°C übersteigen. Wenn also das Kippen einiger Elemente begonnen hat, bedeutet dieses Ergebnis, dass Temperaturfeedbacks in der Lage sind, das Risiko weiterer Kippereignisse zu erhöhen.
Dies ist auch der Fall im Amazonasregenwald, dessen Unterregionen über den sogenannten Feuchtig-keits-Recycling-Feedback miteinander in Beziehung stehen und voneinander abhängen. In dieser Dissertation wird die Bedeutung von Kippereignissen im Detail untersucht, die aufgrund von Dürreperioden zustande kommen. Obwohl man davon ausgehen kann, dass der Regenwald sich an zurückliegende und gegenwärtige Klimabedingungen angepasst hat, kann festgestellt werden, dass die Häu-figkeit von Kippereignissen stark zunimmt, wenn die jeweilige Trockenperiode eine gewisse Intensität übersteigt und damit die Anpassungsfähigkeit des Amazonasregenwalds überschritten wird. In solchen Fällen steigt auch die Häufigkeit von Kippkaskaden unter allen Kippereignissen auf 50% (und mehr) an. In dem Modell, das in dieser Studie entwickelt wurde, zeigt sich, dass der Südosten des Amazonasbeckens am stärksten von den simulierten Trockenheitsmustern betroffen ist. Das ist gleichzeitig die Region, die bereits heute stark unter anthropogener Veränderung leidet, unter anderem aufgrund von großflächiger Abholzung, Viehzucht oder Infrastrukturprojekten.
Zudem wird in dieser Dissertation auf der größeren, erdsystemweiten Skala ein Netzwerk konzeptionalisierter Klimakippelemente aufgebaut. Zu diesem Zweck wird eine umfangreiche Literaturrecherche durchgeführt, die zusammen mit Expertenwissen und den topologischen Eigenschaften der Kippelemente in die Studien mit einfließt. In Klimawandelszenarien können dann Kippkaskaden beobachtet werden, selbst wenn die globale Erderwärmung auf 2°C über dem vorindustriellen Niveau begrenzt werden kann. Außerdem werden die strukturellen Rollen der Klimakippelemente im Netzwerk ermittelt. Während die großen Eisschilde auf Grönland und der Westantarktis viele Kippkaskaden initiieren, ist die Atlantische Umwälzzirkulation für die Weitergabe vieler dieser Kaskaden verantwortlich. In unserem konzeptionellen Modell für Klimakippelemente wird darüber hinaus festgestellt, dass die Eisschilde von besonderer Bedeutung für die Stabilität des Gesamtsystems sind.
Im letzen Teil dieser Dissertation werden die Ergebnisse der Feedbackstudie (CLIMBER-2-Studie) zusammengebracht mit dem konzeptionellen Klimakippelementmodell. Dabei zeigt sich, dass die Wahrscheinlichkeit zusätzlicher Kippereignisse aufgrund der berücksichtigten Temperaturfeedbacks auch ohne das Zuführen eines zusätzlichen CO2-Eintrags in die Atmosphäre leicht ansteigt.
Trotz der konzeptionellen Natur des entwickelten Netzwerkmodells, ist es mit dieser Arbeit erstmals möglich eine Risikoabschätzung über das Auftreten von Kippkaskaden im Erdsystem vorzunehmen. Darüber hinaus können, unter der Annahme globaler Erwärmungsszenarien, auch dynamische Temperaturfeedbacks berücksichtigt werden.
KW - tipping element
KW - nonlinear dynamics
KW - tipping cascade
KW - climate change
KW - complex networks
KW - Klimawandel
KW - komplexe Netzwerke
KW - nichtlineare Dynamiken
KW - Kippkaskade
KW - Kippelement
Y1 - 2021
U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-525140
ER -