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21	Multi-Temporal Glacier-Climate Interactions in Peru’s Queshque Valley (~10˚S): Modeling Contemporary Glacier Change and Interpreting Geomorphic Evidence of Holocene Climate History Shutkin, Tal Yonah 10 November 2022 (has links) No description available. Geography Geomorphology
22	Late glacial (Younger Dryas) glaciers and ice-sheet deglaciation in the Cairngorm Mountains, Scotland : glacier reconstructions and their palaeoclimatic implications Standell, Matthew R. January 2014 (has links) The Cairngorm Mountains contain an outstanding assemblage of glacial landforms from both the deglaciation of the last British Irish Ice Sheet and the Younger Dryas readvance. Glaciers are recognised as sensitive indicators of past and present climate change and, thus, these landforms provide information about past climate and glacier-climate interaction that can be used to contextualise the present climate change. Previous interpretations have left doubt over the extent and style of the Younger Dryas readvance. In addition, the pattern and timing of deglaciation in the southern Cairngorms and, particularly, how local and external ice masses interacted is unclear. New geomorphological mapping from aerial images and fieldwork has been compiled in a GIS for a 600km2 area of the Cairngorm Mountains. This has allowed a complex pattern of ice-dammed lakes and local and regionally sourced ice margins to be reconstructed during the retreat of the last British Irish Ice Sheet. The mapping has been combined with new cosmogenic surface exposure ages taken from areas of hummocky moraine previously subject to differing age interpretations. The effect of moraine denudation on apparent 10Be ages has been checked by inverse modelling of the 10Be concentration vs. boulder height. The results indicate more extensive Younger Dryas glaciation, with glacier reconstructions and equilibrium-line altitudes (ELAs) comparable with the surrounding areas. Reconstruction of both valley and plateau-fed glaciers are presented, with modelling of local topoclimatic factors, such as radiation, avalanche and snow drifting, combined with precipitation gradients, explaining most of the variation within the glacier ELAs. The geomorphological evidence and palaeoclimatic inferences are important, alongside a growing number of palaeoglaciological studies, in acting as evaluation areas for current numerical models of ice-sheet growth and decay. 551.31
23	Quaternary glaciation of central Banks Island, NT, Canada Lakeman, Thomas Ryan Unknown Date No description available. Laurentide Ice Sheet Last Glacial Maximum Ice Sheet Dynamics Sea Level Change Glaciation Banks Island Beaufort Sea Arctic Canada Glacial Geomorphology
24	Rock Avalanches on Glaciers: Processes and Implications Reznichenko, Natalya January 2012 (has links) This thesis examines the role of rock avalanches in tectonically active terrains including the effects of the deposits on glacier behaviour and their contribution to moraine formation. The chronologies of mountain glacier fluctuations, based on moraine ages, are widely used to infer regional climate change and are often correlated globally. In actively uplifting mountain ranges rock avalanches that travel onto the ablation zone of a glacier can reduce ice-surface melting by insulating the ice. This can cause buried ice to thicken due to slower ablation and can signiﬁcantly alter the overall glacier mass balance. This glacier response to supraglacial rock avalanche deposits can confound apparent climatic signals extracted from moraine chronologies. This thesis investigates the processes through which rock avalanche deposits may affect glaciers and develops a new technique to identify the presence of rock avalanche debris in glacial moraines. From laboratory experiments on the effects of debris on ice ablation it is demonstrated that the rate of underlying ice ablation is controlled by diurnal cyclicity and is amplified at high altitude and in lower latitudes. The relatively low permeability of rock avalanche sediment in comparison with non-rock avalanche supraglacial debris cover contributes to the suppression of ablation, at least partly because it greatly reduces the advection of heat from rain water to the underlying ice. The laboratory findings are supplemented by field investigations of two recent rock avalanche deposits on glaciers in the Southern Alps of New Zealand. This work demonstrates that the rock avalanche deposits are very thick (10 m at Aoraki/Mt. Cook and 7m at Mt. Beatrice) and almost stopped the ablation of the overlying ice. This resulted in the formation of an ice-platform more than 30 m high. This led to a reduction of the existing negative mass balance of the affected Tasman and Hooker Glaciers. There was little noticeable alteration of the overall glacial regime due to the small scale of the debris covered area (4 and 1% of the ablation zones for the Tasman and Hooker Glaciers, respectively) but there is a significant contribution to supraglacial debris, which is passively transported toward the terminus. A conceptual model of the response of mountain valley glaciers to emplacement of extensive rock avalanche debris on the ablation zone has been proposed for the effect of this type of debris on terminal moraine formation based on enhanced ‘dumping’ of supraglacial sediments. A new technique has been developed to distinguish rock-avalanche-derived sediment from sediment of glacial origin, based on the sedimentary characteristics of the finest fraction. Examination of rock avalanche sediment under the Scanning Electron Microscope showed that finer particles tend to form strong clumps, which comprise many smaller (down to nanometre-scale) clasts, named here ‘agglomerates’. These agglomerates are present in the ﬁne fraction of all examined rock avalanche deposits and absent in known non-rock-avalanche-derived glacial sediments. The agglomerates are characteristics of sediment produced under the high-stress conditions of rock avalanche emplacement and contrast with lower-stress process sub- and en-glacial environments. It is demonstrated that these agglomerates are present in some moraines in the Southern Alps of New Zealand that have been attributed to climate fluctuation. Consequently, this technique has the potential to resolve long-standing arguments about the role of rock avalanches in moraine formation, and to enhance the use of moraines in palaeoclimatological studies. Rock avalanche supraglacial rock avalanche comminution glacier moraine glacial sediment ablation debris-cover glacial mass balance advance retreat glacial regime glacial geomorphology aclimatic advance microsedimentology agglomerates palaeoclimate moraine chronology rock-avalanche-driven advance the Southern Alps of New Zealand Norway
25	Die Eisrandtäler im Karakorum: Verbreitung, Genese und Morphodynamik des lateroglazialen Sedimentformenschatzes / Lateroglacial valleys in the Karakoram: Distribution, genesis and morphodynamics of lateroglacial sediment associations Iturrizaga, Lasafam 28 November 2005 (has links) No description available. 910 550 Karakorum Himalaya Quartär Vergletscherung Geomorphologie Glazialmorphologie Lateroglaziale Sedimente Paraglaziale/Transglaziale Sedimente Gletscherschwankungen Geographie (PPN621264008)
26	RECONSTRUCTING ICE SHEET SURFACE CHANGES IN WESTERN DRONNING MAUD LAND, ANTARCTICA Jennifer C H Newall (10724127) 29 April 2021 (has links) <p>Understanding climate-driven changes in global land-based ice volume is a critical component in our capability to predict how global sea level will rise as a consequence of the current human-driven climate change. At the last glacial maximum (LGM, which peaked around 20 ka), ephemeral ice sheets covered vast regions of the northern hemisphere while both the Greenland and Antarctic ice sheets were more extensive than at present. As global temperatures rose at the transition into the Holocene, driving the LGM deglaciation, eustatic sea level rose by approximately 125 m. The east Antarctic ice sheet (EAIS) is the largest ice sheet on Earth today, holding an ice volume equivalent to ca. 53 m rise in global sea level. Considering current trends in global climate, specifically rapidly increasing atmospheric CO<sub>2</sub> levels and global temperature, it is important to improve our understanding of how the EAIS will respond to global warming so that we can make better predictions of future sea level changes to guide community adaptation and planning efforts. Numerical ice sheet models which inform projections of future ice volume changes, and can, therefore, yield projections of sea level rise, rely on empirical data to test their ability to accurately represent former and present ice configurations. However, there is a general lack of data on the paleoglaciology of the EAIS along the western Dronning Maud Land (DML) margin. In order to address this situation, the paleoglaciology of western DML forms the focus of the work presented in this thesis.</p><p><b> </b></p><p>Together with collaborators within the MAGIC-DML consortium (Mapping, Measuring and Modelling Antarctic Geomorphology and Ice Change in Dronning Maud Land) that provides the funding for this MS project, the author has performed geomorphological mapping across western DML; an area of approximately 200,000 km<sup>2</sup>. The results of the mapping presented in this thesis will provide the basis for a detailed glacial reconstruction of the region. The geomorphological mapping was completed almost entirely by remote sensing using very high-resolution (sub-meter in the panchromatic) WordView-2 and WorldView-3 (WV) satellite imagery, combined with ground validation studies during field work. Compared to Landsat products, the improved spatial resolution provided by WV imagery has fundamentally changed the scale and detail at which remote sensing based geomorphological mapping can be completed. The mapping presented here is focused on the glacial geomorphology of mountain summits and flanks that protrude through the ice sheet’s surface (nunataks). In our study area of western DML these nunatak surfaces make up <0.2 % of the total surface area, and the landforms mapped here are generally smaller than can be identified from Landsat products (30 m spatial resolution). The detail achieved in our mapping, across such a vast, remote area that presents numerous obstacles to accessibility highlights the benefits of utilizing the new VHR WV data. As such an evaluation of the WV data, as applied to geomorphological mapping is presented here together with our mapping of the glacial geomorphology of western DML. The results of which provides evidence of ice having overridden sites at all elevations across the entire study area; from the highest elevation inland nunataks that form the coast-parallel escarpment, to low-elevation emerging nunataks close to the coast. Hence from our studies of the glacial geomorphology of this region we can ascertain that, at some point in the glacial history of western DML, ice covered all of the mountain summits that are exposed today, indicating an ice sheet surface lowering of up to 700 m in some places.</p> Geology Physical Geography Glaciology Quaternary Environments Surface Processes Earth Sciences not elsewhere classified Glacial geomorphology ANTARCTICA East Antarctic Ice Sheet Nunatak nunataks Dronning Maud Land geomorphological mapping
27	Historische und rezente Gletscherstandsschwankungen in den Einzugsgebieten des Cha Lungpa (Mukut-, Hongde- und Tongu-Himalaja sowie Tach Garbo Lungpa), des Khangsar Khola (Annapurna N-Abdachung) und des Kone Khola (Muktinath-, Purkhung- und Chulu-Himalaja) / Historical and recent glacier fluctuations in the catchment areas of the Cha Lungpa (Mukut-, Hongde-, Tongu-Himalaya and Tach Garbo Lungpa), in the Khangsar Khola (Annapurna N-Slope) and in the Kone Khola (Muktinath-, Purkhung- and Chulu-Himalaya) Achenbach, Hermann 23 February 2011 (has links) No description available. 550 Geowissenschaften Geosciences and Geography Gletscher Himalaja Glazialgeomorphologie Subkontinentale Gletscher Historische Gletscherstandsschwankungen Rezenter Gletscherschwund Hochasien Nepal Klimawandel Quartärgeologie Glacier Himalaya Glacial-Geomorphology Subcontinental Glaciers Historical Glacier Fluctuations Recent Glacier Melting High Asia Nepal Climate Change Quaternary Geology 38.82 74.13-74.28 38.15 38.19 QD 000: Physische Geographie QDB 150: Klimatische Geomorphologie QDB 300: Sedimentation {Geomorphologie}
28	Der glazifluviale Formenschatz im Gletschervorfeld des Himalaya und der Versuch einer relativ-zeitlichen Einordnung / Glaciofluvial sequence of forms in the glacier foreland of the Himalayas and their chronological classification Tombrink, Gerrit 23 November 2017 (has links) No description available. 910 550 Himalaya Khumbu Himal Pangong Tso Nepal Indien Hochasien Glaziale Serie Glazifluviale Serie Gletscherschwankungen Fluvialgeomorphologie Hochgebirgsgeomorphologie Glaziologie Vergletscherung Historische Vergletscherungsstadien Rezente Gletscherschmelze Quartärforschung Holozän Klimawandel Flussformen Proglaziale Formen Gletschervorfeld Sander Himalaya Khumbu Himal Pangong Tso Nepal India High Asia Fluvial Geomorphology Glacial Geomorphology Glaciology Glaciation Glacier Historical Glacier Fluctuations Recent Glacier Melting Climate Change Quaternary Science Holocene River River forms Proglacial forms Glacier foreland Sandur Geographie (PPN621264008)

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