@phdthesis{Steding2022,
  author    = {Steding, Svenja},
  title     = {Geochemical and Hydraulic Modeling of Cavernous Structures in Potash Seams},
  doi       = {10.25932/publishup-54818},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-548182},
  school      = {Universit{\"a}t Potsdam},
  pages     = {IX, 104},
  year      = {2022},
  abstract  = {Salt deposits offer a variety of usage types. These include the mining of rock salt and potash salt as important raw materials, the storage of energy in man-made underground caverns, and the disposal of hazardous substances in former mines. The most serious risk with any of these usage types comes from the contact with groundwater or surface water. It causes an uncontrolled dissolution of salt rock, which in the worst case can result in the flooding or collapse of underground facilities. Especially along potash seams, cavernous structures can spread quickly, because potash salts show a much higher solubility than rock salt. However, as their chemical behavior is quite complex, previous models do not account for these highly soluble interlayers. Therefore, the objective of the present thesis is to describe the evolution of cavernous structures along potash seams in space and time in order to improve hazard mitigation during the utilization of salt deposits. The formation of cavernous structures represents an interplay of chemical and hydraulic processes. Hence, the first step is to systematically investigate the dissolution and precipitation reactions that occur when water and potash salt come into contact. For this purpose, a geochemical reaction model is used. The results show that the minerals are only partially dissolved, resulting in a porous sponge like structure. With the saturation of the solution increasing, various secondary minerals are formed, whose number and type depend on the original rock composition. Field data confirm a correlation between the degree of saturation and the distance from the center of the cavern, where solution is entering. Subsequently, the reaction model is coupled with a flow and transport code and supplemented by a novel approach called 'interchange'. The latter enables the exchange of solution and rock between areas of different porosity and mineralogy, and thus ultimately the growth of the cavernous structure. By means of several scenario analyses, cavern shape, growth rate and mineralogy are systematically investigated, taking also heterogeneous potash seams into account. The results show that basically four different cases can be distinguished, with mixed forms being a frequent occurrence in nature. The classification scheme is based on the dimensionless numbers P{\´e}clet and Damk{\"o}hler, and allows for a first assessment of the hazard potential. In future, the model can be applied to any field case, using measurement data for calibration. The presented research work provides a reactive transport model that is able to spatially and temporally characterize the propagation of cavernous structures along potash seams for the first time. Furthermore, it allows to determine thickness and composition of transition zones between cavern center and unaffected salt rock. The latter is particularly important in potash mining, so that natural cavernous structures can be located at an early stage and the risk of mine flooding can thus be reduced. The models may also contribute to an improved hazard prevention in the construction of storage caverns and the disposal of hazardous waste in salt deposits. Predictions regarding the characteristics and evolution of cavernous structures enable a better assessment of potential hazards, such as integrity or stability loss, as well as of suitable mitigation measures.},
  language  = {en}
}
@phdthesis{Zhao2021,
  author    = {Zhao, Xueru},
  title     = {Palaeoclimate and palaeoenvironment evolution from the last glacial maximum into the early holocene (23-8 ka BP) derived from Lago Grande di Monticchio sediment record (S Italy)},
  pages     = {123},
  year      = {2021},
  language  = {en}
}
@phdthesis{Jentsch2021,
  author    = {Jentsch, Anna},
  title     = {Soil gas analytics in geothermal exploration and monitoring},
  doi       = {10.25932/publishup-54403},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-544039},
  school      = {Universit{\"a}t Potsdam},
  pages     = {xxxi, 162},
  year      = {2021},
  abstract  = {Major challenges during geothermal exploration and exploitation include the structural-geological characterization of the geothermal system and the application of sustainable monitoring concepts to explain changes in a geothermal reservoir during production and/or reinjection of fluids. In the absence of sufficiently permeable reservoir rocks, faults and fracture networks are preferred drilling targets because they can facilitate the migration of hot and/or cold fluids. In volcanic-geothermal systems considerable amounts of gas emissions can be released at the earth surface, often related to these fluid-releasing structures. In this thesis, I developed and evaluated different methodological approaches and measurement concepts to determine the spatial and temporal variation of several soil gas parameters to understand the structural control on fluid flow. In order to validate their potential as innovative geothermal exploration and monitoring tools, these methodological approaches were applied to three different volcanic-geothermal systems. At each site an individual survey design was developed regarding the site-specific questions. The first study presents results of the combined measurement of CO2 flux, ground temperatures, and the analysis of isotope ratios (δ13CCO2, 3He/4He) across the main production area of the Los Humeros geothermal field, to identify locations with a connection to its supercritical (T > 374◦C and P > 221 bar) geothermal reservoir. The results of the systematic and large-scale (25 x 200 m) CO2 flux scouting survey proved to be a fast and flexible way to identify areas of anomalous degassing. Subsequent sampling with high resolution surveys revealed the actual extent and heterogenous pattern of anomalous degassing areas. They have been related to the internal fault hydraulic architecture and allowed to assess favourable structural settings for fluid flow such as fault intersections. Finally, areas of unknown structurally controlled permeability with a connection to the superhot geothermal reservoir have been determined, which represent promising targets for future geothermal exploration and development. In the second study, I introduce a novel monitoring approach by examining the variation of CO2 flux to monitor changes in the reservoir induced by fluid reinjection. For that reason, an automated, multi-chamber CO2 flux system was deployed across the damage zone of a major normal fault crossing the Los Humeros geothermal field. Based on the results of the CO2 flux scouting survey, a suitable site was selected that had a connection to the geothermal reservoir, as identified by hydrothermal CO2 degassing and hot ground temperatures (> 50 °C). The results revealed a response of gas emissions to changes in reinjection rates within 24 h, proving an active hydraulic communication between the geothermal reservoir and the earth surface. This is a promising monitoring strategy that provides nearly real-time and in-situ data about changes in the reservoir and allows to timely react to unwanted changes (e.g., pressure decline, seismicity). The third study presents results from the Aluto geothermal field in Ethiopia where an area-wide and multi-parameter analysis, consisting of measurements of CO2 flux, 222Rn, and 220Rn activity concentrations and ground temperatures was conducted to detect hidden permeable structures. 222Rn and 220Rn activity concentrations are evaluated as a complementary soil gas parameter to CO2 flux, to investigate their potential to understand tectono-volcanic degassing. The combined measurement of all parameters enabled to develop soil gas fingerprints, a novel visualization approach. Depending on the magnitude of gas emissions and their migration velocities the study area was divided in volcanic (heat), tectonic (structures), and volcano-tectonic dominated areas. Based on these concepts, volcano-tectonic dominated areas, where hot hydrothermal fluids migrate along permeable faults, present the most promising targets for future geothermal exploration and development in this geothermal field. Two of these areas have been identified in the south and south-east which have not yet been targeted for geothermal exploitation. Furthermore, two unknown areas of structural related permeability could be identified by 222Rn and 220Rn activity concentrations. Eventually, the fourth study presents a novel measurement approach to detect structural controlled CO2 degassing, in Ngapouri geothermal area, New Zealand. For the first time, the tunable diode laser (TDL) method was applied in a low-degassing geothermal area, to evaluate its potential as a geothermal exploration method. Although the sampling approach is based on profile measurements, which leads to low spatial resolution, the results showed a link between known/inferred faults and increased CO2 concentrations. Thus, the TDL method proved to be a successful in the determination of structural related permeability, also in areas where no obvious geothermal activity is present. Once an area of anomalous CO2 concentrations has been identified, it can be easily complemented by CO2 flux grid measurements to determine the extent and orientation of the degassing segment. With the results of this work, I was able to demonstrate the applicability of systematic and area-wide soil gas measurements for geothermal exploration and monitoring purposes. In particular, the combination of different soil gases using different measurement networks enables the identification and characterization of fluid-bearing structures and has not yet been used and/or tested as standard practice. The different studies present efficient and cost-effective workflows and demonstrate a hands-on approach to a successful and sustainable exploration and monitoring of geothermal resources. This minimizes the resource risk during geothermal project development. Finally, to advance the understanding of the complex structure and dynamics of geothermal systems, a combination of comprehensive and cutting-edge geological, geochemical, and geophysical exploration methods is essential.},
  language  = {en}
}
@phdthesis{Hebert2021,
  author    = {H{\´e}bert, Raphaёl},
  title     = {Investigation of vegetation and terrestrial climate variablity during the holocene},
  school      = {Universit{\"a}t Potsdam},
  pages     = {201},
  year      = {2021},
  language  = {en}
}
@phdthesis{Riedl2021,
  author    = {Riedl, Simon},
  title     = {Active tectonics in the Kenya Rift},
  doi       = {10.25932/publishup-53855},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-538552},
  school      = {Universit{\"a}t Potsdam},
  pages     = {xi, 207},
  year      = {2021},
  abstract  = {Magmatische und tektonisch aktive Grabenzonen (Rifts) stellen die Vorstufen entstehender Plattengrenzen dar. Diese sich spreizenden tektonischen Provinzen zeichnen sich durch allgegenw{\"a}rtige Abschiebungen aus, und die r{\"a}umliche Verteilung, die Geometrie, und das Alter dieser Abschiebungen l{\"a}sst R{\"u}ckschl{\"u}sse auf die r{\"a}umlichen und zeitlichen Zusammenh{\"a}nge zwischen tektonischer Deformation, Magmatismus und langwelliger Krustendeformation in Rifts zu. Diese Arbeit konzentriert sich auf die St{\"o}rungsaktivit{\"a}t im Kenia-Rift des k{\"a}nozoischen Ostafrikanischen Grabensystems im Zeitraum zwischen dem mittleren Pleistoz{\"a}n und dem Holoz{\"a}n. Um die fr{\"u}hen Stadien der Entstehung kontinentaler Plattengrenzen zu untersuchen, wird in dieser Arbeit eine zeitlich gemittelte minimale Extensionsrate f{\"u}r den inneren Graben des N{\"o}rdlichen Kenia-Rifts (NKR) f{\"u}r die letzten 0,5 Mio Jahre abgeleitet. Die Analyse beruht auf Messungen mit Hilfe des digitalen TanDEM-X-H{\"o}henmodells, um die Abschiebungen entlang der vulkanisch-tektonischen Achse des inneren Grabens des NKR zu kartieren und deren Versatzbetr{\"a}ge zu bestimmen. Mithilfe von vorhandenen Geochronologiedaten der deformierten vulkanischen Einheiten sowie in dieser Arbeit erstellten ⁴⁰Ar/³⁹Ar-Datierungen werden zeitlich gemittelte Extensionsraten berechnet. Die Auswertungen zeigen, dass im inneren Graben des NKR die langfristige Extensionsrate f{\"u}r mittelpleistoz{\"a}ne bis rezente St{\"o}rungen Mindestwerte von 1,0 bis 1,6 mm yr⁻¹ aufweist und lokal allerdings auch Werte bis zu 2,0 mm yr⁻¹ existieren. In Anbetracht der nahezu inaktiven Randst{\"o}rungen des NKR zeigt sich somit, dass sich die Extension auf die Region der aktiven vulkanisch-tektonischen Achse im inneren Graben konzentriert und somit ein fortgeschrittenes Stadium kontinentaler Extensionsprozesse im NKR vorliegt. In dieser Arbeit wird diese r{\"a}umlich fokussierte Extension zudem im Rahmen einer St{\"o}rungsanalyse der j{\"u}ngsten vulkanischen Erscheinungen des Kenia-Rifts betrachtet. Die Arbeit analysiert mithilfe von Gel{\"a}ndekartierungen und eines auf Luftbildern basierenden Gel{\"a}ndemodells die St{\"o}rungscharakteristika der etwa 36 tausend Jahre alten Menengai-Kaldera und der umliegenden Gebiete im zentralen Kenia-Rift. Im Allgemeinen sind die holoz{\"a}nen St{\"o}rungen innerhalb des Rifts reine, NNO-streichende Abschiebungen, die somit das gegenw{\"a}rtige tektonische Spannungsfeld wiederspiegeln; innerhalb der Menengai-Kaldera sind die jungen Strukturen jedoch von andauernder magmatischer Aktivit{\"a}t und von Aufdomung {\"u}berpr{\"a}gt. Die Kaldera befindet sich im Zentrum eines sich aktiv dehnenden Riftsegments und zusammen mit den anderen quart{\"a}ren Vulkanen des Kenia-Rifts lassen sich diese Bereiche als Kernpunkte der extensionalen St{\"o}rungsaktivit{\"a}t verstehen, die letztlich zu einer weiter entwickelten Phase magmengest{\"u}tzter Kontinentalseparation f{\"u}hren werden. Die bereits seit dem Terti{\"a}r andauernde St{\"o}rungsaktivit{\"a}t im Kenia-Rift f{\"u}hrt zur Zergliederung der gr{\"o}ßeren Rift-Senken in kleinere Segmente und beeinflusst die Sedimentologie und die Hydrologie dieser Riftbecken. Gegenw{\"a}rtig sind die meisten, durch St{\"o}rungen begrenzten Becken des Kenia-Rifts hydrologisch isoliert, sie waren aber w{\"a}hrend feuchter Klimaphasen hydrologisch miteinander verbunden; in dieser Arbeit untersuche ich deshalb auch diese hydrologische Verbindung der Rift-Becken f{\"u}r die Zeit der Afrikanischen Feuchteperiode des fr{\"u}hen Holoz{\"a}ns. Mithilfe der Analyse von digitalen Gel{\"a}ndemodellen, unter Ber{\"u}cksichtigung von geomorphologischen Anzeigern f{\"u}r Seespiegelhochst{\"a}nde, Radiokarbondatierungen und einer {\"U}bersicht {\"u}ber Fossiliendaten konnten zwei kaskadierende Flusssysteme aus diesen Daten abgeleitet werden: eine Flusskaskade in Richtung S{\"u}den und eine in Richtung Norden. Beide Kaskaden haben die derzeit isolierten Becken w{\"a}hrend des fr{\"u}hen Holoz{\"a}ns durch {\"u}berlaufende Seen und eingeschnittene Schluchten miteinander verbunden. Diese hydrologische Verbindung f{\"u}hrte zu der Ausbreitung aquatischer Fauna entlang des Rifts, und gleichzeitig stellte die Wasserscheide zwischen den beiden Flusssystemen den einzigen terrestrischen Ausbreitungskorridor dar, der eine {\"U}berquerung des Kenia-Rifts erm{\"o}glichte. Diese tektonisch-geomorphologische Rekonstruktion erkl{\"a}rt die heute isolierten Vorkommen nilotischer Fischarten in den Riftseen Kenias sowie die isolierten Vorkommen Guineo-Congolischer S{\"a}ugetiere in W{\"a}ldern {\"o}stlich des Kenia-Rifts, die sich {\"u}ber die Wasserscheide im Kenia-Rift ausbreiten konnten. Auf l{\"a}ngeren Zeitskalen sind solche Phasen hydrologischer Verbindung und Phasen der Isolation wiederholt aufgetreten und zeigen sich in wechselnden pal{\"a}o{\"o}kologischen Indikatoren in Sedimentbohrkernen. Hier stelle ich einen Sedimentbohrkern aus dem Koora-Becken des S{\"u}dlichen Kenia-Rifts vor, der einen Datensatz der Pal{\"a}o-Umweltbedingungen der letzten 1 Million Jahre beinhaltet. Dieser Datensatz zeigt, dass etwa vor 400 tausend Jahren die zuvor relativ stabilen Umweltbedingungen zum Erliegen kamen und tektonische, hydrologische und {\"o}kologische Ver{\"a}nderungen dazu f{\"u}hrten, dass die Wasserverf{\"u}gbarkeit, die Grasland-Vergesellschaftungen und die Bedeckung durch Baumvegetation zunehmend st{\"a}rkeren und h{\"a}ufigeren Schwankungen unterlagen. Diese großen Ver{\"a}nderungen fallen zeitlich mit Phasen zusammen, in denen das s{\"u}dliche Becken des Kenia-Rifts von vulkanischer und tektonischer Aktivit{\"a}t besonders betroffen war. Die vorliegende Arbeit zeigt deshalb deutlich, inwiefern die tektonischen und geomorphologischen Gegebenheiten im Zuge einer zeitlich langanhaltenden Extension die Hydrologie, die Pal{\"a}o-Umweltbedingungen sowie die Biodiversit{\"a}t einer Riftzone beeinflussen k{\"o}nnen.},
  language  = {en}
}
@phdthesis{vanderVeen2021,
  author    = {van der Veen, Iris},
  title     = {Defining moisture sources and (palaeo)environmental conditions using isotope geochemistry in the NW Himalaya},
  doi       = {10.25932/publishup-51439},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-514397},
  school      = {Universit{\"a}t Potsdam},
  pages     = {152},
  year      = {2021},
  abstract  = {Anthropogenic climate change alters the hydrological cycle. While certain areas experience more intense precipitation events, others will experience droughts and increased evaporation, affecting water storage in long-term reservoirs, groundwater, snow, and glaciers. High elevation environments are especially vulnerable to climate change, which will impact the water supply for people living downstream. The Himalaya has been identified as a particularly vulnerable system, with nearly one billion people depending on the runoff in this system as their main water resource. As such, a more refined understanding of spatial and temporal changes in the water cycle in high altitude systems is essential to assess variations in water budgets under different climate change scenarios. However, not only anthropogenic influences have an impact on the hydrological cycle, but changes to the hydrological cycle can occur over geological timescales, which are connected to the interplay between orogenic uplift and climate change. However, their temporal evolution and causes are often difficult to constrain. Using proxies that reflect hydrological changes with an increase in elevation, we can unravel the history of orogenic uplift in mountain ranges and its effect on the climate. In this thesis, stable isotope ratios (expressed as δ2H and δ18O values) of meteoric waters and organic material are combined as tracers of atmospheric and hydrologic processes with remote sensing products to better understand water sources in the Himalayas. In addition, the record of modern climatological conditions based on the compound specific stable isotopes of leaf waxes (δ2Hwax) and brGDGTs (branched Glycerol dialkyl glycerol tetraethers) in modern soils in four Himalayan river catchments was assessed as proxies of the paleoclimate and (paleo-) elevation. Ultimately, hydrological variations over geological timescales were examined using δ13C and δ18O values of soil carbonates and bulk organic matter originating from sedimentological sections from the pre-Siwalik and Siwalik groups to track the response of vegetation and monsoon intensity and seasonality on a timescale of 20 Myr. I find that Rayleigh distillation, with an ISM moisture source, mainly controls the isotopic composition of surface waters in the studied Himalayan catchments. An increase in d-excess in the spring, verified by remote sensing data products, shows the significant impact of runoff from snow-covered and glaciated areas on the surface water isotopic values in the timeseries. In addition, I show that biomarker records such as brGDGTs and δ2Hwax have the potential to record (paleo-) elevation by yielding a significant correlation with the temperature and surface water δ2H values, respectively, as well as with elevation. Comparing the elevation inferred from both brGDGT and δ2Hwax, large differences were found in arid sections of the elevation transects due to an additional effect of evapotranspiration on δ2Hwax. A combined study of these proxies can improve paleoelevation estimates and provide recommendations based on the results found in this study. Ultimately, I infer that the expansion of C4 vegetation between 20 and 1 Myr was not solely dependent on atmospheric pCO2, but also on regional changes in aridity and seasonality from to the stable isotopic signature of the two sedimentary sections in the Himalaya (east and west). This thesis shows that the stable isotope chemistry of surface waters can be applied as a tool to monitor the changing Himalayan water budget under projected increasing temperatures. Minimizing the uncertainties associated with the paleo-elevation reconstructions were assessed by the combination of organic proxies (δ2Hwax and brGDGTs) in Himalayan soil. Stable isotope ratios in bulk soil and soil carbonates showed the evolution of vegetation influenced by the monsoon during the late Miocene, proving that these proxies can be used to record monsoon intensity, seasonality, and the response of vegetation. In conclusion, the use of organic proxies and stable isotope chemistry in the Himalayas has proven to successfully record changes in climate with increasing elevation. The combination of δ2Hwax and brGDGTs as a new proxy provides a more refined understanding of (paleo-)elevation and the influence of climate.},
  language  = {en}
}
@phdthesis{Liu2021,
  author    = {Liu, Sisi},
  title     = {The history of plant diversity change and community assemply a high-altitude and high-latitude ecosystems inferred from sedimentary (ancient) DNA and pollen},
  school      = {Universit{\"a}t Potsdam},
  year      = {2021},
  language  = {en}
}
@phdthesis{Petersen2021,
  author    = {Petersen, Gesa Maria},
  title     = {Source studies of small earthquakes in the AlpArray: CMT inversion, seismo-tectonic analysis and methodological developments},
  doi       = {10.25932/publishup-52563},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-525635},
  school      = {Universit{\"a}t Potsdam},
  pages     = {151},
  year      = {2021},
  abstract  = {Centroid moment tensor inversion can provide insight into ongoing tectonic processes and active faults. In the Alpine mountains (central Europe), challenges result from low signal-to-noise ratios of earthquakes with small to moderate magnitudes and complex wave propagation effects through the heterogeneous crustal structure of the mountain belt. In this thesis, I make use of the temporary installation of the dense AlpArray seismic network (AASN) to establish a work flow to study seismic source processes and enhance the knowledge of the Alpine seismicity. The cumulative thesis comprises four publications on the topics of large seismic networks, seismic source processes in the Alps, their link to tectonics and stress field, and the inclusion of small magnitude earthquakes into studies of active faults. Dealing with hundreds of stations of the dense AASN requires the automated assessment of data and metadata quality. I developed the open source toolbox AutoStatsQ to perform an automated data quality control. Its first application to the AlpArray seismic network has revealed significant errors of amplitude gains and sensor orientations. A second application of the orientation test to the Turkish KOERI network, based on Rayleigh wave polarization, further illustrated the potential in comparison to a P wave polarization method. Taking advantage of the gain and orientation results of the AASN, I tested different inversion settings and input data types to approach the specific challenges of centroid moment tensor (CMT) inversions in the Alps. A comparative study was carried out to define the best fitting procedures. The application to 4 years of seismicity in the Alps (2016-2019) substantially enhanced the amount of moment tensor solutions in the region. We provide a list of moment tensors solutions down to magnitude Mw 3.1. Spatial patterns of typical focal mechanisms were analyzed in the seismotectonic context, by comparing them to long-term seismicity, historical earthquakes and observations of strain rates. Additionally, we use our MT solutions to investigate stress regimes and orientations along the Alpine chain. Finally, I addressed the challenge of including smaller magnitude events into the study of active faults and source processes. The open-source toolbox Clusty was developed for the clustering of earthquakes based on waveforms recorded across a network of seismic stations. The similarity of waveforms reflects both, the location and the similarity of source mechanisms. Therefore the clustering bears the opportunity to identify earthquakes of similar faulting styles, even when centroid moment tensor inversion is not possible due to low signal-to-noise ratios of surface waves or oversimplified velocity models. The toolbox is described through an application to the Zakynthos 2018 aftershock sequence and I subsequently discuss its potential application to weak earthquakes (Mw<3.1) in the Alps.},
  language  = {en}
}
@phdthesis{Runge2021,
  author    = {Runge, Alexandra},
  title     = {Multispectral time series analyses with Landsat and Sentinel-2 to assess permafrost disturbances in North Siberia},
  doi       = {10.25932/publishup-52206},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-522062},
  school      = {Universit{\"a}t Potsdam},
  pages     = {xxiv, 134},
  year      = {2021},
  abstract  = {Permafrost is warming globally, which leads to widespread permafrost thaw and impacts the surrounding landscapes, ecosystems and infrastructure. Especially ice-rich permafrost is vulnerable to rapid and abrupt thaw, resulting from the melting of excess ground ice. Local remote sensing studies have detected increasing rates of abrupt permafrost disturbances, such as thermokarst lake change and drainage, coastal erosion and RTS in the last two decades. All of which indicate an acceleration of permafrost degradation. In particular retrogressive thaw slumps (RTS) are abrupt disturbances that expand by up to several meters each year and impact local and regional topographic gradients, hydrological pathways, sediment and nutrient mobilisation into aquatic systems, and increased permafrost carbon mobilisation. The feedback between abrupt permafrost thaw and the carbon cycle is a crucial component of the Earth system and a relevant driver in global climate models. However, an assessment of RTS at high temporal resolution to determine the dynamic thaw processes and identify the main thaw drivers as well as a continental-scale assessment across diverse permafrost regions are still lacking. In northern high latitudes optical remote sensing is restricted by environmental factors and frequent cloud coverage. This decreases image availability and thus constrains the application of automated algorithms for time series disturbance detection for large-scale abrupt permafrost disturbances at high temporal resolution. Since models and observations suggest that abrupt permafrost disturbances will intensify, we require disturbance products at continental-scale, which allow for meaningful integration into Earth system models. The main aim of this dissertation therefore, is to enhance our knowledge on the spatial extent and temporal dynamics of abrupt permafrost disturbances in a large-scale assessment. To address this, three research objectives were posed: 1. Assess the comparability and compatibility of Landsat-8 and Sentinel-2 data for a combined use in multi-spectral analysis in northern high latitudes. 2. Adapt an image mosaicking method for Landsat and Sentinel-2 data to create combined mosaics of high quality as input for high temporal disturbance assessments in northern high latitudes. 3. Automatically map retrogressive thaw slumps on the landscape-scale and assess their high temporal thaw dynamics. We assessed the comparability of Landsat-8 and Sentinel-2 imagery by spectral comparison of corresponding bands. Based on overlapping same-day acquisitions of Landsat-8 and Sentinel-2 we derived spectral bandpass adjustment coefficients for North Siberia to adjust Sentinel-2 reflectance values to resemble Landsat-8 and harmonise the two data sets. Furthermore, we adapted a workflow to combine Landsat and Sentinel-2 images to create homogeneous and gap-free annual mosaics. We determined the number of images and cloud-free pixels, the spatial coverage and the quality of the mosaic with spectral comparisons to demonstrate the relevance of the Landsat+Sentinel-2 mosaics. Lastly, we adapted the automatic disturbance detection algorithm LandTrendr for large-scale RTS identification and mapping at high temporal resolution. For this, we modified the temporal segmentation algorithm for annual gradual and abrupt disturbance detection to incorporate the annual Landsat+Sentinel-2 mosaics. We further parametrised the temporal segmentation and spectral filtering for optimised RTS detection, conducted further spatial masking and filtering, and implemented a binary object classification algorithm with machine-learning to derive RTS from the LandTrendr disturbance output. We applied the algorithm to North Siberia, covering an area of 8.1 x 106 km2. The spectral band comparison between same-day Landsat-8 and Sentinel-2 acquisitions already showed an overall good fit between both satellite products. However, applying the acquired spectral bandpass coefficients for adjustment of Sentinel-2 reflectance values, resulted in a near-perfect alignment between the same-day images. It can therefore be concluded that the spectral band adjustment succeeds in adjusting Sentinel-2 spectral values to those of Landsat-8 in North Siberia. The number of available cloud-free images increased steadily between 1999 and 2019, especially intensified after 2016 with the addition of Sentinel-2 images. This signifies a highly improved input database for the mosaicking workflow. In a comparison of annual mosaics, the Landsat+Sentinel-2 mosaics always fully covered the study areas, while Landsat-only mosaics contained data-gaps for the same years. The spectral comparison of input images and Landsat+Sentinel-2 mosaic showed a high correlation between the input images and the mosaic bands, testifying mosaicking results of high quality. Our results show that especially the mosaic coverage for northern, coastal areas was substantially improved with the Landsat+Sentinel-2 mosaics. By combining data from both Landsat and Sentinel-2 sensors we reliably created input mosaics at high spatial resolution for comprehensive time series analyses. This research presents the first automatically derived assessment of RTS distribution and temporal dynamics at continental-scale. In total, we identified 50,895 RTS, primarily located in ice-rich permafrost regions, as well as a steady increase in RTS-affected areas between 2001 and 2019 across North Siberia. From 2016 onward the RTS area increased more abruptly, indicating heightened thaw slump dynamics in this period. Overall, the RTS-affected area increased by 331 \% within the observation period. Contrary to this, five focus sites show spatiotemporal variability in their annual RTS dynamics, alternating between periods of increased and decreased RTS development. This suggests a close relationship to varying thaw drivers. The majority of identified RTS was active from 2000 onward and only a small proportion initiated during the assessment period. This highlights that the increase in RTS-affected area was mainly caused by enlarging existing RTS and not by newly initiated RTS. Overall, this research showed the advantages of combining Landsat and Sentinel-2 data in northern high latitudes and the improvements in spatial and temporal coverage of combined annual mosaics. The mosaics build the database for automated disturbance detection to reliably map RTS and other abrupt permafrost disturbances at continental-scale. The assessment at high temporal resolution further testifies the increasing impact of abrupt permafrost disturbances and likewise emphasises the spatio-temporal variability of thaw dynamics across landscapes. Obtaining such consistent disturbance products is necessary to parametrise regional and global climate change models, for enabling an improved representation of the permafrost thaw feedback.},
  language  = {en}
}
@phdthesis{Stuff2021,
  author    = {Stuff, Maria},
  title     = {Iron isotope fractionation in carbonatite melt systems},
  doi       = {10.25932/publishup-51992},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-519928},
  school      = {Universit{\"a}t Potsdam},
  pages     = {xvi, 137},
  year      = {2021},
  abstract  = {Carbonatite magmatism is a highly efficient transport mechanism from Earth's mantle to the crust, thus providing insights into the chemistry and dynamics of the Earth's mantle. One evolving and promising tool for tracing magma interaction are stable iron isotopes, particularly because iron isotope fractionation is controlled by oxidation state and bonding environment. Meanwhile, a large data set on iron isotope fractionation in igneous rocks exists comprising bulk rock compositions and fractionation between mineral groups. Iron isotope data from natural carbonatite rocks are extremely light and of remarkably high variability. This resembles iron isotope data from mantle xenoliths, which are characterized by a variability in δ56Fe spanning three times the range found in basalts, and by the extremely light values of some whole rock samples, reaching δ56Fe as low as -0.69  per mille in a spinel lherzolite. Cause to this large range of variations may be metasomatic processes, involving metasomatic agents like volatile bearing high-alkaline silicate melts or carbonate melts. The expected effects of metasomatism on iron isotope fractionation vary with parameters like melt/rock-ratio, reaction time, and the nature of metasomatic agents and mineral reactions involved. An alternative or additional way to enrich light isotopes in the mantle could be multiple phases of melt extraction. To interpret the existing data sets more knowledge on iron isotope fractionation factors is needed. To investigate the behavior of iron isotopes in the carbonatite systems, kinetic and equilibration experiments in natro-carbonatite systems between immiscible silicate and carbonate melts were performed in an internally heated gas pressure vessel at intrinsic redox conditions at temperatures between 900 and 1200 °C and pressures of 0.5 and 0.7 GPa. The iron isotope compositions of coexisting silicate melt and carbonate melt were analyzed by solution MC-ICP-MS. The kinetic experiments employing a Fe-58 spiked starting material show that isotopic equilibrium is obtained after 48 hours. The experimental studies of equilibrium iron isotope fractionation between immiscible silicate and carbonate melts have shown that light isotopes are enriched in the carbonatite melt. The highest Δ56Fesil.m.-carb.melt (mean) of 0.13  per mille was determined in a system with a strongly peralkaline silicate melt composition (ASI ≥ 0.21, Na/Al ≤ 2.7). In three systems with extremely peralkaline silicate melt compositions (ASI between 0.11 and 0.14) iron isotope fractionation could analytically not be resolved. The lowest Δ56Fesil.m.-carb.melt (mean) of 0.02  per mille was determined in a system with an extremely peralkaline silicate melt composition (ASI ≤ 0.11 , Na/Al ≥ 6.1). The observed iron isotope fractionation is most likely governed by the redox conditions of the system. Yet, in the systems, where no fractionation occurred, structural changes induced by compositional changes possibly overrule the influence of redox conditions. This interpretation implicates, that the iron isotope system holds the potential to be useful not only for exploring redox conditions in magmatic systems, but also for discovering structural changes in a melt. In situ iron isotope analyses by femtosecond laser ablation coupled to MC-ICP-MS on magnetite and olivine grains were performed to reveal variations in iron isotope composition on the micro scale. The investigated sample is a melilitite bomb from the Salt Lake Crater group at Honolulu (Oahu, Hawaii), showing strong evidence for interaction with a carbonatite melt. While magnetite grains are rather homogeneous in their iron isotope compositions, olivine grains span a far larger range in iron isotope ratios. The variability of δ56Fe in magnetite is limited from - 0.17  per mille (± 0.11  per mille, 2SE) to +0.08  per mille (± 0.09  per mille, 2SE). δ56Fe in olivine range from -0.66 per mille (± 0.11  per mille, 2SE) to +0.10  per mille (± 0.13  per mille, 2SE). Olivine and magnetite grains hold different informations regarding kinetic and equilibrium fractionation due to their different Fe diffusion coefficients. The observations made in the experiments and in the in situ iron isotope analyses suggest that the extremely light iron isotope signatures found in carbonatites are generated by several steps of isotope fractionation during carbonatite genesis. These may involve equilibrium and kinetic fractionation. Since iron isotopic signatures in natural systems are generated by a combination of multiple factors (pressure, temperature, redox conditions, phase composition and structure, time scale), multi tracer approaches are needed to explain signatures found in natural rocks.},
  language  = {en}
}