TY  - JOUR
A1  - Acharya, B. S.
A1  - Aramo, C.
A1  - Babic, A.
A1  - Barrio, J. A.
A1  - Baushev, Anton N.
A1  - Tjus, J. Becker
A1  - Berge, David
A1  - Bohacova, M.
A1  - Bonardi, A.
A1  - Brown, A.
A1  - Bugaev, V.
A1  - Bulik, Tomasz
A1  - Burton, M.
A1  - Busetto, G.
A1  - Caraveo, P. A.
A1  - Carosi, R.
A1  - Carr, John
A1  - Chadwick, Paula M.
A1  - Chudoba, J.
A1  - Conforti, V.
A1  - Connaughton, V.
A1  - Contreras, J. L.
A1  - Cotter, G.
A1  - Dazzi, F.
A1  - De Franco, A.
A1  - de la Calle, I.
A1  - Lopez, R. de los Reyes
A1  - De Lotto, B.
A1  - De Palma, F.
A1  - Di Girolamo, T.
A1  - Di Giulio, C.
A1  - Di Pierro, F.
A1  - Dournaux, J. -L.
A1  - Dwarkadas, Vikram V.
A1  - Ebr, J.
A1  - Egberts, Kathrin
A1  - Fesquet, M.
A1  - Fleischhack, H.
A1  - Font, L.
A1  - Fontaine, G.
A1  - Foerster, A.
A1  - Füßling, Matthias
A1  - Garcia, B.
A1  - Lopez, R. Garcia
A1  - Garczarczyk, M.
A1  - Gargano, F.
A1  - Garrido, D.
A1  - Gaug, M.
A1  - Giglietto, N.
A1  - Giordano, F.
A1  - Giuliani, A.
A1  - Godinovic, N.
A1  - Gonzalez, M. M.
A1  - Grabarczyk, T.
A1  - Hassan, T.
A1  - Hoerandel, J.
A1  - Hrabovsky, M.
A1  - Hrupec, D.
A1  - Humensky, T. B.
A1  - Huovelin, J.
A1  - Jamrozy, M.
A1  - Janecek, P.
A1  - Kaaret, P. E.
A1  - Katz, U.
A1  - Kaufmann, S.
A1  - Khelifi, B.
A1  - Kluzniak, W.
A1  - Kocot, J.
A1  - Komin, N.
A1  - Kubo, H.
A1  - Kushida, J.
A1  - Lamanna, G.
A1  - Lee, W. H.
A1  - Lenain, J. -P.
A1  - Lohse, T.
A1  - Lombardi, S.
A1  - Lopez-Coto, R.
A1  - Lopez-Oramas, A.
A1  - Lucarelli, F.
A1  - Maccarone, M. C.
A1  - Maier, G.
A1  - Majumdar, P.
A1  - Malaguti, G.
A1  - Mandat, D.
A1  - Mazziotta, Mario Nicola
A1  - Meagher, K.
A1  - Mirabal, N.
A1  - Morselli, A.
A1  - Moulin, Emmanuel
A1  - Niemiec, J.
A1  - Nievas, M.
A1  - Nishijima, K.
A1  - Nosek, D.
A1  - Nunio, F.
A1  - Ohishi, M.
A1  - Ohm, S.
A1  - Ong, R. A.
A1  - Orito, R.
A1  - Otte, N.
A1  - Palatka, M.
A1  - Pareschi, G.
A1  - Pech, M.
A1  - Persic, M.
A1  - Pohl, Manuela
A1  - Prouza, M.
A1  - Quirrenbach, A.
A1  - Raino, S.
A1  - Fernandez, G. Rodriguez
A1  - Romano, Patrizia
A1  - Rovero, A. C.
A1  - Rudak, B.
A1  - Schovanek, P.
A1  - Shayduk, M.
A1  - Siejkowski, H.
A1  - Sillanpaa, A.
A1  - Stefanik, S.
A1  - Stolarczyk, T.
A1  - Szanecki, M.
A1  - Szepieniec, T.
A1  - Tejedor, L. A.
A1  - Telezhinsky, Igor O.
A1  - Teshima, M.
A1  - Tibaldo, L.
A1  - Tibolla, O.
A1  - Tovmassian, G.
A1  - Travnicek, P.
A1  - Trzeciak, M.
A1  - Vallania, P.
A1  - van Eldik, C.
A1  - Vercellone, S.
A1  - Vigorito, C.
A1  - Wagner, S. J.
A1  - Wakely, S. P.
A1  - Weinstein, A.
A1  - Wierzcholska, A.
A1  - Wilhelm, Alina
A1  - Wojcik, P.
A1  - Yoshikoshi, T.
T1  - The Cherenkov Telescope Array potential for the study of young supernova remnants
JF  - Astroparticle physics
N2  - Supernova remnants (SNRs) are among the most important targets for gamma-ray observatories. Being prominent non-thermal sources, they are very likely responsible for the acceleration of the bulk of Galactic cosmic rays (CRS). To firmly establish the SNR paradigm for the origin of cosmic rays, it should be confirmed that protons are indeed accelerated in, and released from, SNRs with the appropriate flux and spectrum. This can be done by detailed theoretical models which account for microphysics of acceleration and various radiation processes of hadrons and leptons. The current generation of Cherenkov telescopes has insufficient sensitivity to constrain theoretical models. A new facility, the Cherenkov Telescope Array (CTA), will have superior capabilities and may finally resolve this long standing issue of high-energy astrophysics. We want to assess the capabilities of CTA to reveal the physics of various types of SNRs in the initial 2000 years of their evolution. During this time, the efficiency to accelerate cosmic rays is highest. We perform time-dependent simulations of the hydrodynamics, the magnetic fields, the cosmic-ray acceleration, and the non-thermal emission for type Ia, Ic and IIP SNRs. We calculate the CTA response to the y-ray emission from these SNRs for various ages and distances, and we perform a realistic analysis of the simulated data. We derive distance limits for the detectability and resolvability of these SNR types at several ages. We test the ability of CTA to reconstruct their morphological and spectral parameters as a function of their distance. Finally, we estimate how well CTA data will constrain the theoretical models. (C) 2014 Elsevier B.V. All rights reserved.
KW  - Acceleration of particles
KW  - Gamma rays: General
KW  - ISM: Supernova remnants
KW  - Radiation mechanisms: Non-termal
Y1  - 2015
U6  - https://doi.org/10.1016/j.astropartphys.2014.08.005
SN  - 0927-6505
SN  - 1873-2852
VL  - 62
SP  - 152
EP  - 164
PB  - Elsevier
CY  - Amsterdam
ER  - 
TY  - JOUR
A1  - Klasen, Michael
A1  - Pohl, Martin
A1  - Sigl, Günter
T1  - Indirect and direct search for dark matter
JF  - Progress in particle and nuclear physics
N2  - The majority of the matter in the universe is still unidentified and under investigation by both direct and indirect means. Many experiments searching for the recoil of dark-matter particles off target nuclei in underground laboratories have established increasingly strong constraints on the mass and scattering cross sections of weakly interacting particles, and some have even seen hints at a possible signal. Other experiments search for a possible mixing of photons with light scalar or pseudo-scalar particles that could also constitute dark matter. Furthermore, annihilation or decay of dark matter can contribute to charged cosmic rays, photons at all energies, and neutrinos. Many existing and future ground-based and satellite experiments are sensitive to such signals. Finally, data from the Large Hadron Collider at CERN are scrutinized for missing energy as a signature of new weakly interacting particles that may be related to dark matter. In this review article we summarize the status of the field with an emphasis on the complementarity between direct detection in dedicated laboratory experiments, indirect detection in the cosmic radiation, and searches at particle accelerators. (C) 2015 Elsevier B.V. All rights reserved.
KW  - Dark matter
KW  - Direct searches
KW  - Indirect searches
KW  - LHC
Y1  - 2015
U6  - https://doi.org/10.1016/j.ppnp.2015.07.001
SN  - 0146-6410
SN  - 1873-2224
VL  - 85
SP  - 1
EP  - 32
PB  - Elsevier
CY  - Amsterdam
ER  -