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Ambiguous landscape histories can arise from equivocal or incomplete geomorphological, sedimentological or geochronological evidence. In this study, we apply quantitative analyses to robustly assess the origin and age of a field of rounded mounds, known as ‘The Hillocks’. Using clast analysis, the sediment is shown to be consistent with a landslide origin but inconsistent with other glacial sediments in the region. Cosmogenic 10Be exposure age dating suggests The Hillocks formed ~8 ka. Ground‐penetrating radar reveals that the deposit rests upon deltaic foreset beds; combined with topographical data, we calculate a deposit volume of ~15–27 M m3, consistent with the estimated volume of the proposed source area. Overall, our data support a rock avalanche origin, indicating that by 8 ka the valley was ice‐free at The Hillocks’ location, and the level of Lake Wakatipu was lower than 340 m asl by this time. The Dart River delta shoreline was situated somewhere between The Hillocks and the present day shoreline at that time, and has prograded at a maximum average rate of 1 m a?1 since ~8 ka. These findings are significant given the lack of landforms by which to constrain glacial or post‐glacial landscape histories in this region of New Zealand. Copyright © 2019 John Wiley & Sons, Ltd. 相似文献
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Harold Lovell Stephen J. Livingstone Clare M. Boston Adam D. Booth Robert D. Storrar Iestyn D. Barr 《地球表面变化过程与地形》2019,44(13):2685-2702
The development of glacier karst at the margins of melting ice sheets produces complex glaciofluvial sediment-landform assemblages that provide information on ice sheet downwasting processes. We present the first combined geomorphological, sedimentological and geophysical investigation of the Brampton Kame Belt, an important glaciofluvial depositional zone at the centre of the last British-Irish Ice Sheet. Ground-penetrating radar (GPR) data allow the broad scale internal architecture of ridges (eskers) and flat-topped hills (ice-walled lake plains) to be determined at four sites. In combination with sediment exposures, these provide information on lateral and vertical variations in accretion styles, depositional boundaries, and grain size changes. Building on existing work on the subject, we propose a refined model for the formation of ice-walled lake plains resulting from the evolution and collapse of major drainage axes into lakes as stable glacier karst develops during deglaciation. The internal structure of esker ridges demonstrates variations in sedimentation that can be linked to differences in ridge morphologies across the kame belt. This includes low energy flow conditions and multiple accretion phases identified within large S-N oriented esker ridges; and fluctuating water pressures, hyperconcentrated flows, and significant deformation within a fragmented SW–NE oriented esker ridge. In combination with updated geomorphological mapping, this work allows us to identify two main styles of drainage within the kame belt: (1) major drainage axes aligned broadly S-N that extend through the entire kame belt and collapsed into a chain of ice-walled lakes; and (2) a series of smaller, fragmented SW–NE aligned esker ridges that represent ice-marginal drainage as the ice sheet receded south-eastwards up the Vale of Eden. Our study demonstrates the importance of integrated geomorphological, sedimentological and geophysical investigations in order to understand complex and polyphase glaciofluvial sediment-landform assemblages. © 2019 John Wiley & Sons, Ltd. © 2019 John Wiley & Sons, Ltd. 相似文献
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Lasafam Iturrizaga 《GeoJournal》2001,54(2-4):397-428
Lateroglacial landforms play a major role in the geomorphological landscape assemblage of the Karakoram Mountains. Nevertheless, in the past they have received only little attention in the glacial-geomorphological literature. In this article, the lateroglacial landscape will be presented as a geomorphological landscape unit. The Karakoram glaciers with lengths of up to 60 km are accompanied by lateroglacial sediment complexes over tens of kilometers. Besides their large horizontal distribution, they are spread over a considerable vertical range and occur between 2500 m–5000 m.The traditional view is that primary processes of rock disintegration such as ice avalanches and freeze-thaw processes as well as glaciofluvial sediments are the main debris suppliers for the formation of lateroglacial sediment complexes. However, the investigation of the lateroglacial sediment landscape of the Karakoram glaciers showed, that firstly the secondary debris supply in form of reworking of older glacigenic deposits (Late glacial slope moraines) represents a major debris source. Secondly, the lateroglacial sediments are composed to a major part of debris supplies from the tributary valleys. In this regard, the sediment input by mudflow events accords a prominent role. Therefore a considerable proportion of the lateroglacial sediments is of non-glacial origin. This fact has to be taken into consideration regarding glacier reconstruction in recent unglaciated mountain valleys. Further on, resedimented mudflow deposits could be identified as important parent material for recent lateral moraine formation. The distribution of lateroglacial valleys (`lateral moraine valleys') was traditionally closely linked to differences in insolation, which are in the subtropical latitude very high (`ablation valleys'). Therefore the S-faced valley flank was seen as the favourable location for lateroglacial valleys. However, field observations on more than 20 glaciers in the Karakoram Mountains proved that lateroglacial valleys occur in all exposures, and can be even absent in S-exposure. Topographical factors seem to be more important than insolation differences for the distribution pattern. Only the distribution of `true ablation valleys' can be regarded as a result of insolation differences. In fact, they can act as initial form for the formation of lateral moraine valleys. 相似文献
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