Your search keyword '"U-shaped valley"' showing total 198 results

1. Numerical modelling of geothermal heat flux and ice velocity influencing the thermal conditions of the Priestley Glacier trough (northern Victoria Land, Antarctica)

Author

Mario Gaeta, G. Scarascia Mugnozza, Carlo Baroni, G.M. Marmoni, Cristina Perinelli, Salvatore Martino, and M.C. Salvatore

Subjects

geography, geography.geographical_feature_category, Ice stream, Bedrock, Geothermal heating, ice velocity, geothermal flux, Glacier, Valley thermal states, Geothermal flux, Ice velocity,Thermal modelling, Priestley Glacier, Antarctica, Atmospheric sciences, U-shaped valley, Heat flux, Antarctica, thermal modelling, Glacial period, valley thermal states, Geothermal gradient, Priestley Glacier, Geology, Priestley glacier, Earth-Surface Processes

Abstract

Deep geothermal contributions can affect the thermal equilibrium of glacial systems, which can induce changes in their thermal state. These changes can be influenced by glacier dynamics and by the different ice flow velocities experienced over time, which dictate the static and dynamic interactions with glacial trough bedrock. To assess such interactions and to weight the effects of ice mass thermalisations on bedrock, 2D multistage numerical modelling was performed for Priestley Glacier (an outlet glacier) in the East Antarctic glacial system (northern Victoria Land), which has experienced extreme heat flux variations related to rifting and late Cenozoic volcanism. The thermal evolution of Priestley Glacier over the last ~500 ka was modelled considering the mutual contributions of local and deep thermal sources through a parametric variation in the geothermal heat flux. The ice mass velocity was indirectly taken into account by assuming an ice persistence time over the bedrock under timelled considering the mutual contributions of local and deep thermal sources through a parametric variation in the geothermal heat flux. The ice mass velocity was indirectly taken into account by assuming an ice persistence time over the bedrock under time-dependent modelling conditions. Ice thickness and geothermal heat fluxes, varying from 50 to 120 mW/m2, were conditions are strongly linked in determining the thermal state of the glacier base and consequently its impact on basal erosion. According to the adopted ice stationing levels, heat flux conditions not exceeding 70 mW/m2 are needed for preserving a dry-based glacier only assuming velocity conditions equal to or lower than those observed to date along Priestley Glacier. Assuming increased velocity conditions, the glacier sensitivity to heat fluxes decreases, and high to very high heat fluxes are not sufficient to cause glacier base transitions to wet states.

Published

2021

2. Large-Scale Rock Slope Deformation from the Tablelands and Lookout Hills of Western Newfoundland, Canada

Author

Ian Spooner, Gerald Osborn, John C. Gosse, Ian A. Brookes, Antony R. Berger, and Dewey W. Dunnington

Subjects

Paleontology, geography, U-shaped valley, geography.geographical_feature_category, Bedrock, Glacier, Glacial period, Fault scarp, Permafrost, Shear strength (discontinuity), Geology, Holocene

Abstract

Five large gravitational slope deformation features (GSDFs) in the Lookout Mountain-Tablelands region of western Newfoundland exemplify bedrock slope instabilities in eastern Canada. The Lookout Hills GSDF (8.3 km3) on Bonne Bay (glacial trough) may be the largest GSDF in eastern Canada. It appears to be a post-glacial feature, has vertical total displacement up to 100 m, and exhibits a complex arrangement of scarps and fissures. Four other large GSDFs occur along the walls of glacial troughs in the Tablelands of Western Newfoundland with estimated volumes between 1 and 2 km3. All five features are above steep slopes and have the potential to become catastrophic massive rock slope failures. While it is tempting to link the failure in all 5 GSDFs to the removal of laterally supporting bedrock or glacier ice during the late Pleistocene, the location of these deformations may simply relate to slope steepness. Non-glacial, first order controls on the deformation include changes in the effective shear strength and opening of fractures owing to Holocene permafrost thaw may have induced failure. No discernible movement has occurred in the Tablelands GSDFs in the last 50 years. Nevertheless, the Lookout Hills GSDF requires more detailed study to determine the potential for future movement as rapid collapse into the adjacent fjord may present significant risk to coastal residents, infrastructure and marine ecosystems.

Published

2020

3. Deglaciation of the North Cascade Range, Washington and British Columbia, from the Last Glacial Maximum to the Holocene

Author

J.L. Riedel

Subjects

geography, Geography (General), geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geography, Planning and Development, Glacier, Environmental Science (miscellaneous), 010502 geochemistry & geophysics, Glacier morphology, deglaciation, 01 natural sciences, ice age, U-shaped valley, Moraine, Earth and Planetary Sciences (miscellaneous), Wisconsin glaciation, Deglaciation, G1-922, Physical geography, Glacial period, pleistocene, Ice sheet, Geology, north cascades, 0105 earth and related environmental sciences

Abstract

Glacial retreat from the North Cascade Range after the Last Glacial Maximum (LGM) at approximately 21 ka until the end of the Pleistocene at 11.6 ka was complex and included both continental and alpine glaciers. Alpine valley glaciers reached their maximum extent before 21.4 ka, then underwent a punctuated retreat to valley heads. In the south, beyond the reach of ice sheet glaciation, several end moraines were deposited after the LGM. Moraines marking a re-advance of alpine glaciers to 5 km below modern glaciers were deposited from 13.7 to 11.6 ka.The Cordilleran Ice Sheet flowed south from near 52° north latitude in British Columbia into the North Cascades. At its maximum size the ice sheet covered more than 500 km2 and had a surface elevation of 2200 m in upper Skagit valley. Deglaciation commenced about 16 ka by frontal retreat of ice flanking the mountains. Surface lowering eventually exposed regional hydrologic divides and stranded ice masses more than 1000 m thick in valleys. Isolated fragments of the ice sheet disintegrated rapidly from 14.5 to 13.5 ka, with the pattern of deglaciation in each valley controlled by valley orientation, topography, and climate. Like alpine glaciers to the south, retreat of the ice sheet remnants was slowed by millennial scale climate fluctuations that produced at least one large recessional moraine, and multiple lateral moraines and kame terraces from elevations of 200-1400 m in most valleys. Large volumes of glacial meltwater flowed through the North Cascades and was concentrated in the Skagit and Methow rivers. Outburst floods from deep proglacial lakes spilled across divides and down steep canyons, depositing coarse gravel terraces and alluvial fans at valley junctions.Climate at the LGM was characterized by a mean summer temperature 6 to 7 ºC cooler than today, and 40% lower mean annual precipitation. Persistence of this climate for thousands of years before the LGM caused a 750-1000 m decrease in alpine glacier equilibrium line altitudes (ELA). In the southern North Cascades at 16 ka, glacial ELAs were 500-700 m lower than today, and during advances from 13.7 to 11.6 ka alpine glacier ELAs were 200-400 m lower.

Published

2017

4. Late Quaternary glaciation of the northern Urals: a review and new observations

Author

Valery Astakhov

Subjects

010506 paleontology, Archeology, geography, geography.geographical_feature_category, Pleistocene, Geology, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, Paleontology, U-shaped valley, Moraine, Wisconsin glaciation, Glacial period, Ice sheet, Bull Lake glaciation, Geomorphology, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

This is a synthesis of the glacial history of the northern Urals undertaken using published works and the results of geological surveys as well as recent geochronometric and remote sensing data. The conclusions differ from the classical model that considers the Urals as an important source of glacial ice and partly from the modern reconstructions. The principal supporting evidence for the conventional model – Uralian erratics found on the adjacent plains – is ambiguous because Uralian clasts were also delivered by a thick external ice sheet overriding the mountains during the Middle Pleistocene. Alternative evidence presented in this paper indicates that in the late Quaternary the Ural mountains produced only valley glaciers that partly coalesced in the western piedmont to form large piedmont lobes. The last maximum glaciation occurred in the Early Valdaian time at c. 70–90 ka when glacial ice from the Kara shelf invaded the lowlands and some montane valleys but an icecap over the mountains was not formed. The moraines of the alpine glaciation are preserved only beyond the limits of the Kara ice sheet and therefore cannot be younger than MIS 4. More limited glaciation during MIS 2 generated small alpine moraines around the cirques of the western Urals (Mangerud et al. 2008: Quaternary Science Reviews 27, 1047). The largest moraines of Transuralia were probably produced by the outlet glaciers of a Middle Pleistocene ice sheet that formed on the western plains and discharged across the Polar Urals. The resultant scheme of limited mountain glaciation is possibly also applicable as a model for older glacial cycles.

Published

2017

5. Glacial-geomorphic study of the Thajwas glacier valley, Kashmir Himalayas, India

Author

Reyaz Ahmad Dar, Shakil Ahmad Romshoo, Omar Jaan, and Khalid Omar Murtaza

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Landform, Glacial landform, Last Glacial Maximum, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, U-shaped valley, Moraine, Glacial period, Geomorphology, Geology, Terminal moraine, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Glacial-geomorphic studies provide vital information to make inferences about the effect of glacial advance and retreat on the geomorphology of an area. In the present study, glacial-geomorphic landforms of the Thajwas glacial valley in the upper reaches of the Indus, Kashmir Himalayas were mapped using geospatial technology validated with GPS-based field observations and ground photography. The glacial-geomorphic landforms were digitized using ASTER DEM (30 m resolution), Landsat ETM+ satellite imagery (30 m resolution) and Google Earth (1 m resolution) data. Results showed that Google Earth imagery, supported by field validation, is very useful for the interpretation of glacial-geomorphic landscapes and relief features at micro- and meso-scales. However, morphometric characteristics of landforms are best obtained using DEM overlaid onto the Landsat ETM+ satellite data. Glaciers in the valley are presently confined along the south and southwestern slopes. However, the significant role played by glaciers in shaping the geomorphic landforms and their subsequent preservation within the scenic landscape under the Late Quaternary climatic conditions are remarkably evident. The glacial-geomorphic landforms, especially terminal moraine, glacial trough and cirques observed in the valley aided the reconstruction of palaeo-glacial setting of the area. Morphology, shape and location of terminal and lateral moraine ridges were used to establish the palaeo-glacial extents, glacial volume and the number of glacial advances of the Thajwas glacier. The maximum elevation of the lateral moraines was used to define the former Equilibrium-Line Altitude (ELA). The greater rock excavation to form a large valley during the last glacial maximum might have induced isostatic rock uplift/exhumation in the glacier source area. It is observed that the concomitant retreat of the north-facing glacial cirques has played an important role in expanding the glacial valley and limiting the topographic relief.

Published

2017

6. First cosmogenic geochronology from the Lesser Caucasus: Late Pleistocene glaciation and rock glacier development in the Karçal Valley, NE Turkey

Author

Attila Çiner, İhsan Çiçek, Volkan Dede, Levent Uncu, and Mehmet Sarikaya

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Pleistocene, Rock glacier, Geology, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, Archaeology, Paleontology, U-shaped valley, Surface exposure dating, Moraine, Deglaciation, Glacial period, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Evidence of widespread alpine glaciations during the Late Pleistocene in mid-latitudes has long attracted attention of researchers. However, there were no studies that contain absolute ages in the Lesser Caucasus despite the fact that it is one of the major glaciated regions in Eurasia. Here, we present first cosmogenic 36Cl surface exposure ages from the Karcal Mountains (41.24° N, 42.06° E, 3431 m a.s.l., above sea level) which is located in the most western part of the Lesser Caucasus in the northeastern Anatolia. In the Karcal Mountains, there are numerous valleys that have experienced significant glaciations since Late Pleistocene. We have investigated one of the largest valleys, the east-facing Karcal Valley, that hosts even a small (2926 m a.s.l.) recent glacier located at above 3000 m a.s.l. Fossil and recent rock glaciers along with lateral and recessional moraines exist in the valley. We conducted the study in two stages. First, we mapped the geomorphological units in the Karcal Valley in detail based on our field works and aerial photography. Later, we collected 10 rock samples from the fossil rock glacier and recessional moraines for cosmogenic 36Cl surface exposure dating. The results outline a glacial chronology that is typical of the Last Glacial Maximum. Although the maximum extent and timing of the glaciation is not exactly known as lateral and terminal moraines were not suitable for sampling, recessional moraines indicate that the Karcal Valley palaeoglacier deglaciation started at least 19.9 ± 1.2 ka ago. Fossil rock glacier samples were dated to 15.7 ± 1.3 ka. These quantitative results are first in the Lesser Caucasus and compatible with previous ages obtained from other valleys in the nearby Eastern Black Sea region, Anatolian and some of the European Mountains.

Published

2017

7. The recent deglaciation of Kolahoi valley in Kashmir Himalaya, India in response to the changing climate

Author

Irfan Rashid, Shakil Ahmad Romshoo, and Tariq Abdullah

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Glacial landform, Tidewater glacier cycle, Geology, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, Glacier mass balance, U-shaped valley, Moraine, Climatology, Deglaciation, Glacial period, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

In the present study, the retreat of Kolahoi glacier was mapped from the satellite observations and historical maps supplemented by the extensive field observations to understand the recent deglaciation of the Kolahoi valley, Kashmir Himalaya, India. The glacier has retreated by 2.85 km during the last 157 years from 1857 to 2014 with an average retreat of about 18.2 m year−1; however, the glacier snout has shown higher recession during the last decade. The geomorphological evidence reveals glaciation of the Kolahoi valley during the Quaternary. These evidences include glacial till at Pahalgam and Aru besides terminal and lateral moraines at Lidderwat, Satlanjan and Kolahoi Gunj in the Kolahoi valley. The glacier has shrunk by 2.81 km2 during the last 51 years (1962–2013) losing an ice volume of 0.30 km3. The observed glacier changes were correlated with the climate data from PMIP3-CMIP5 models. The temperatures are predicted to increase almost ten times more than that observed during the Last Glacial Maximum (LGM). The future temperature is predicted to rise between 0.18 °C and 0.61 °C per decade under RCP 2.6 and RCP 8.5 respectively. The projected rise in the temperature, if realized, will have an adverse effect on the glaciers and would, in all likelihood, adversely affect the water availability for various sectors in the region.

Published

2017

8. Pattern of Holocene glaciation in the monsoon-dominated Kosa Valley, central Himalaya, Uttarakhand, India

Author

S. Nawaz Ali, Dhirendra Singh Bagri, Pinkey Bisht, Y. P. Sundriyal, Poonam, Naresh Rana, Sunil Singh, and Navin Juyal

Subjects

010506 paleontology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Last Glacial Maximum, Glacier, 01 natural sciences, Paleontology, U-shaped valley, Moraine, Outwash plain, Wisconsin glaciation, Glacial period, Geomorphology, Geology, Holocene, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Reconstruction based on the geomorphology, lateral moraine stratigraphy, and limited optical chronology indicate that the monsoon-dominated Kosa Valley experienced four glacial advances during the late glacial to late Holocene. The oldest and most extensive glaciation, which is termed as Raj Bank Stage-1 (RBS-1), is represented by the degraded moraine ridge. This glaciation remains undated; however, the chronology of outwash terrace gravel dated to 12.7 ± 1.3 ka indicates that the RBS-1 probably represents the Last Glacial Maximum (LGM). The second glacial advance (RBS-2) is preserved as a curvilinear lateral moraine and is dated to 6.1 ± 0.4 ka. The third glacial advance viz. RBS-3 is bracketed between 5.0 ± 0.5 and 4.0 ± 0.4 ka. Following this, the glacier receded in pulses that are represented by two distinct recessional moraines (RBS-3a and b). The forth glacial stage (RBS-4), which is dated between 2.2 ± 0.2 and 1.6 ± 0.2 ka, shows a pulsating recession and is represented by a prominent recessional moraine (RBS-4a). Whereas, presence of unconsolidated, poorly defined moraine mounds proximal to the glacier snout are ascribed as neoglacial advance corresponding to the Little Ice Age (LIA). With the limited chronometric data, we speculated that the glaciation was driven during the weak to moderate Indian Summer Monsoon (ISM) aided by lowered temperature. Presence of recessional moraines associated with mid-Holocene glacial phase indicate that the monsoon-dominated glaciers respond sensitively to minor (sub-millennial scale) changes in temperature and precipitation conditions. The observations are broadly in accordance with the studies carried out in other monsoon-dominated valleys in the central Himalaya, implying that in ISM dominated regions, lowered temperature seems to be the major driver of glaciations during the late glacial to late Holocene.

Published

2017

9. Late Glacial glacier-climate modeling in two valleys on the eastern slope of Samdainkangsang Peak, Nyaiqentanggulha Mountains

Author

Xiangke Xu, Guocheng Dong, Baolin Pan, Gang Hu, Weili Bi, Chaolu Yi, and Jinhua Liu

Subjects

010506 paleontology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Glacial landform, Glacier, 01 natural sciences, Glacier mass balance, U-shaped valley, Moraine, Paleoclimatology, Glacial earthquake, General Earth and Planetary Sciences, Glacial period, Geomorphology, Geology, 0105 earth and related environmental sciences

Abstract

Well-preserved Late Glacial moraines in the Barenduo and Yuqiongqu valleys on the eastern slope of the Samdainkangsang Peak present an opportunity to reconstruct glacier extents and examine the character of the climate during the Late Glacial stage in the Nyaiqentanggulha Mountains. This study employs a coupled mass-balance and ice-flow model to reconstruct the glacier extents in the two valleys and assess the magnitudes of temperature and precipitation change during the Late Glacial period. Model results indicate that during the Late Glacial, the Barenduo valley contained an ice volume of 1.67×108 m3, with the equilibrium-line altitude (ELA) being ~5500 m asl; and the Yuqiongqu valley had an ice volume of 5.56×108 m3, with the ELA being ~5470 m asl. A climate scenario, temperature depression of 2.6–2.8°C and 60–70%, percent of modern (1981–2010) precipitation, can sustain both of the Late Glacial glacier extents in the two valleys. A 50% increase or decrease from modern precipitation would have been coupled with the respective Late Glacial temperature depressions of 1.6 and 3.0°C in the Barenduo valley, and 2.1 and 2.8°C in the Yuqiongqu valley.

Published

2016

10. A cosmogenic 3He chronology of late Quaternary glacier fluctuations in North Island, New Zealand (39°S)

Author

Shaun R. Eaves, Dougal Townsend, Joerg M. Schaefer, Gisela Winckler, Brent V. Alloway, and Andrew Mackintosh

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geology, Last Glacial Maximum, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, U-shaped valley, Surface exposure dating, Moraine, Climatology, Wisconsin glaciation, Deglaciation, Physical geography, Glacial period, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Mountain glaciers advance and retreat primarily in response to changes in climate. Establishing the timing and magnitude of mountain glacier fluctuations from geological records can thus help to identify the drivers and mechanisms of past climate change. In this study, we use cosmogenic 3He surface exposure dating and tephrochronology to constrain the timing of past glaciation on Tongariro massif in central North Island, New Zealand (39°S). Exposure ages from moraine boulders show that valley glaciation persisted between c. 30–18 ka, which coincides with the global Last Glacial Maximum. Reinterpretation of moraine tephrostratigraphy, using major element geochemistry analysis, shows that ice retreat and climatic amelioration at the last glacial termination was well underway prior to 14 ka. The equilibrium line altitude in central North Island, during the Last Glacial Maximum, was c. 1400–1550 m above sea level, which is c. 930–1080 m lower than present. Considering the uncertainties in the glacial reconstruction and temperature lapse rates, we estimate that this equilibrium line altitude lowering equates to a temperature depression of 5.6 ± 1.1 °C, relative to present. Our mapping and surface exposure dating also show evidence for an earlier period of glaciation, of similar magnitude to the Last Glacial Maximum, which culminated prior to 57 ka, probably during Marine Isotope Stage 4. Good agreement between the timing and magnitude of glacier fluctuations in central North Island and the Southern Alps indicate a response to a common climatic forcing during the last glacial cycle.

Published

2016

11. Extensive glaciation in Transbaikalia, Siberia, at the Last Glacial Maximum

Author

Martin Margold, Artem L. Gurinov, Natalya V. Reznichenko, John D. Jansen, Charles Mifsud, Alexandru T. Codilean, Frank Preusser, and David Fink

Subjects

010506 paleontology, Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Earth science, Glacial landform, Ice field, Geology, Glacier, Last Glacial Maximum, 15. Life on land, 01 natural sciences, U-shaped valley, Moraine, Wisconsin glaciation, Institut für Geowissenschaften, Glacial period, Physical geography, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Successively smaller glacial extents have been proposed for continental Eurasia during the stadials of the last glacial period leading up to the Last Glacial Maximum (LGM). At the same time the large mountainous region east of Lake Baikal, Transbaikalia, has remained unexplored in terms of glacial chronology despite clear geomorphological evidence of substantial past glaciations. We have applied cosmogenic Be-10 exposure dating and optically stimulated luminescence to establish the first quantitative glacial chronology for this region. Based on eighteen exposure ages from five moraine complexes, we propose that large mountain ice fields existed in the Kodar and Udokan mountains during Oxygen Isotope Stage 2, commensurate with the global LGM. These ice fields fed valley glaciers (>100 km in length) reaching down to the Chara Depression between the Kodar and Udokan mountains and to the valley of the Vitim River northwest of the Kodar Mountains. Two of the investigated moraines date to the Late Glacial, but indications of incomplete exposure among some of the sampled boulders obscure the specific details of the post-LGM glacial history. In addition to the LGM ice fields in the highest mountains of Transbaikalia, we report geomorphological evidence of a much more extensive, ice-cap type glaciation at a time that is yet to be firmly resolved. (C) 2015 Elsevier Ltd. All rights reserved.

Published

2016

12. Late glacial 10Be ages for glacial landforms in the upper region of the Taibai glaciation in the Qinling Mountain range, China

Author

Wei Zhang, Zhijiu Cui, Xu Zhao, Beibei Liu, Xiao Liu, Liang Liu, Rui Liu, Jonathan M. Harbor, and Yixin Chen

Subjects

010506 paleontology, geography, geography.geographical_feature_category, Plateau, Glacial landform, Geology, Last Glacial Maximum, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, U-shaped valley, Physical geography, Glacial period, Cosmogenic nuclide, Quaternary, Geomorphology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Glacial landforms are well preserved on Taibai Mountain (3767 m), the main peak of the Qinling mountain range located south of the Loess Plateau and east of the Qinghai-Tibet Plateau. The timing and extent of Quaternary glaciation in the study area is important for reconstructing Quaternary environmental change however numerical ages for glaciation in this study area have not previously been well resolved. Using terrestrial in situ cosmogenic nuclides we dated four samples collected from two glacially eroded rock steps in the upper part of a valley near the main peak, in an area previously identified as having been occupied by ice during the Taibai glaciation. The 10Be results are all late glacial in age: 18.6 ± 1.1 ka, 16.9 ± 1.0 ka, 16.9 ± 1.1 ka and 15.1 ± 1.0 ka. The spatial pattern of ages in the valley suggests fast retreat, with horizontal and vertical retreat rates estimated to be on the order of 0.4 and 0.09 m a−1, respectively. A simple extrapolation of these retreat rates from the ages at the two sample sites suggests that the glacier retreat began during Last Glacial Maximum and that glaciers disappeared from the main peak by about 15 ka.

Published

2016

13. Widespread erosion on high plateaus during recent glaciations in Scandinavia

Author

Mads Faurschou Knudsen, Jane Lund Andersen, Søren B. Nielsen, Jesper V. Olsen, David L. Egholm, Dmitry Tikhomirov, Henriette Linge, Vivi Kathrine Pedersen, Sheng Xu, John D. Jansen, and Derek Fabel

Subjects

010504 meteorology & atmospheric sciences, Science, General Physics and Astronomy, 010502 geochemistry & geophysics, SEDIMENT, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, AMS STANDARDS, Paleontology, Glacial period, RATES, lcsh:Science, 0105 earth and related environmental sciences, LANDSCAPE EVOLUTION, geography, Multidisciplinary, geography.geographical_feature_category, CLIMATE-CHANGE, Landform, SURFACES, fungi, COSMOGENIC NUCLIDES, Glacier, General Chemistry, 15. Life on land, FENNOSCANDIAN ICE-SHEET, WESTERN NORWAY, U-shaped valley, 13. Climate action, BE-10 EXPOSURE AGES, Erosion, lcsh:Q, Ice sheet, Quaternary, Global cooling, Geology

Abstract

Glaciers create some of Earth’s steepest topography; yet, many areas that were repeatedly overridden by ice sheets in the last few million years include extensive plateaus. The distinct geomorphic contrast between plateaus and the glacial troughs that dissect them has sustained two long-held hypotheses: first, that ice sheets perform insignificant erosion beyond glacial troughs, and, second, that the plateaus represent ancient pre-glacial landforms bearing information of tectonic and geomorphic history prior to Pliocene–Pleistocene global cooling (~3.5 Myr ago). Here we show that the Fennoscandian ice sheets drove widespread erosion across plateaus far beyond glacial troughs. We apply inverse modelling to 118 new cosmogenic 10Be and 26Al measurements to quantify ice sheet erosion on the plateaus fringing the Sognefjorden glacial trough in western Norway. Our findings demonstrate substantial modification of the pre-glacial landscape during the Quaternary, and that glacial erosion of plateaus is important when estimating the global sediment flux to the oceans., The contribution of surface processes to the long-term evolution of plateau surfaces on high-latitude passive margins is poorly understood. Here, the authors show that recent glacial erosion on plateaus in western Scandinavia was widespread and may have contributed substantially to the sediment flux to the oceans.

Published

2018

14. Glacial history of Mt Chelmos, Peloponnesus, Greece

Author

Emmanuel Skourtsos, Philip D. Hughes, and Richard J. J. Pope

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Pleistocene, Geology, Ocean Engineering, Glacier, Last Glacial Maximum, Cirque glacier, 010502 geochemistry & geophysics, 01 natural sciences, Paleontology, U-shaped valley, Moraine, Glacial period, Younger Dryas, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

Mt Chelmos in the Peloponnesus was glaciated by a plateau ice field during the most extensive Pleistocene glaciation. Valley glaciers radiated out from an ice field over the central plateau of the massif. The largest glaciations are likely to be Middle Pleistocene in age. Smaller valley and cirque glaciers formed later and boulders on the moraines of these glacial phases have been dated using 36Cl terrestrial cosmogenic nuclide exposure dating. These ages indicate a Late Pleistocene age with glacier advance/stabilization at 40?30 ka, glacier retreat at 23?21 ka and advance/stabilization at 13?10 ka. This indicates that the glacial maximum of the last cold stage occurred during Marine Isotope Stage 3, several thousand years before the global Last Glacial Maximum (Marine Isotope Stage 2). The last phase of moraine-building occurred at the end of the Pleistocene, possibly during the Younger Dryas.

Published

2015

15. Surface exposure chronology of the Waimakariri glacial sequence in the Southern Alps of New Zealand: Implications for MIS-2 ice extent and LGM glacial mass balance

Author

David Alexander, James Shulmeister, David Fink, D. H. Bell, and Henrik Rother

Subjects

Glacier ice accumulation, geography, geography.geographical_feature_category, Last Glacial Maximum, Glacier, U-shaped valley, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Moraine, Climatology, Earth and Planetary Sciences (miscellaneous), Wisconsin glaciation, Physical geography, Glacial period, Bull Lake glaciation, Geology

Abstract

During the late Quaternary, the Southern Alps of New Zealand experienced multiple episodes of glaciation with large piedmont glaciers reaching the coastal plains in the west and expanding into the eastern alpine forelands. Here, we present a new 10Be exposure age chronology for a moraine sequence in the Waimakariri Valley (N-Canterbury), which has long been used as a reference record for correlating glacial events across New Zealand and the wider Southern Hemisphere. Our data indicate that the Waimakariri glacier reached its maximum last glaciation extent prior to ∼26 ka well before the global last glaciation maximum (LGM). This was followed by a gradual reduction in ice volume and the abandonment of the innermost LGM moraines at about 17.5 ka. Significantly, we find that during its maximum extent, the Waimakariri glacier overflowed the Avoca Plateau, previously believed to represent a mid-Pleistocene glacial surface (i.e. MIS 8). At the same time, the glacier extended to a position downstream of the Waimakariri Gorge, some 15 km beyond the previously mapped LGM ice limit. We use a simple steady-state mass balance model to test the sensitivity of past glacial accumulation to various climatic parameters, and to evaluate possible climate scenarios capable of generating the ice volume required to reach the full local-LGM extent. Model outcomes indicate that under New Zealand's oceanic setting, a cooling of 5 °C, assuming modern precipitation levels, or a cooling of 6.5 °C, assuming a one third reduction in precipitation, would suffice to drive the Waimakariri glacier to the eastern alpine forelands (Canterbury Plains). Our findings demonstrate that the scale of LGM glaciation in the Waimakariri Valley and adjacent major catchments, both in terms of ice volume and downvalley ice extent, has been significantly underestimated. Our observation that high-lying glacial surfaces, so far believed to represent much older glacial episodes, were glaciated during the LGM, challenges the conventional geomorphic model of glaciation in New Zealand where the vertical arrangement of glacial landform-associations is used to assign successively older glaciation ages.

Published

2015

16. Glacial geomorphology of the Maidika region, Tibetan Plateau

Author

Miranda S. Lindholm and Jakob Heyman

Subjects

geography, geography.geographical_feature_category, Plateau, 010504 meteorology & atmospheric sciences, Glacial landform, Geography, Planning and Development, Ice field, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, Lineation, U-shaped valley, Moraine, Earth and Planetary Sciences (miscellaneous), Glacial period, Geomorphology, Geology, 0105 earth and related environmental sciences

Abstract

We present a glacial geomorphological map at a scale of 1:200,000 of the Maidika region in the southeastern part of the central Tibetan Plateau covering 13,600 km2. Based on the 90 m resolution SRTM elevation model, the 30 m resolution ASTER GDEM elevation model, and the Landsat ETM+ satellite imagery of 30/15 m resolution, we have mapped glacial valleys, marginal moraines, glacial lineations, and hummocky terrain. Glacial landforms occur frequently and indicate extensive past glaciation with alpine style valley glaciers as well as more extensive ice fields. Of particular interest is the presence of glacial lineation swarms, which is unusual for the Tibetan Plateau glacial landform record. Based on the distribution of glacial landforms, we present a generalized maximum glacial extent reconstruction covering 6045 km2 or 44% of the map.

Published

2015

17. Glacial Karst Aspects About the DeKalb Mounds in Illinois, USA

Author

Michael Iannicelli

Subjects

geography, U-shaped valley, geography.geographical_feature_category, Glacial landform, Glacial striation, Geochemistry, Glacier, Post-glacial rebound, Glacial period, Ice sheet, Karst, Geomorphology, Geology

Abstract

The glacial dead-ice origin of the DeKalb mounds in DeKalb County, Illinois, USA, is advanced in this study by discussing it within the context of late Wisconsinan glacial karst. Glacial karst is glacial dead-ice topography that resembles carbonate bedrock karst topography. The only difference here is that thermo-erosion or melting of ice by groundwater causes glacial karst, while dissolution of carbonates by groundwater causes bedrock karst. For example, bedrock karst such as haystack hills, dolines and entranceless caves analogously match up to stagnant glacial ice blocks with supraglacial ice pits and entranceless glacial caves. Entranceless bedrock caves are caves with no opening (entranceway) that is big enough for a human, yet contain water and/or accumulations of silt and clay. Although stagnant glacial ice blocks and supraglacial ice pits have been discussed in the literature, entranceless glacial caves is an undeveloped concept which is expounded in this study. An entranceless glacial cave is actually a subglacial/englacial, water-filled cavity formed by thermo-erosion due to active-layer groundwater/talik piping laterally seeping out of the adjoining terrain and into a body of glacial ice, as seen in modern glaciers of Antarctica. This type of water-filled cavity can also be classified as a subglacial or englacial lake. The study also discusses relationships to embryonic DeKalb mounds such as: why a localized part of the continental ice sheet degenerated into stagnant ice blocks; and the Wisconsinan creation of one or more steep depressions in the till plain underlying a DeKalb mound.

Published

2015

18. Glacial geomorphology of the Parlung Zangbo Valley, southeastern Tibetan Plateau

Author

Chen Renrong, Shangzhe Zhou, Yingbin Deng, and Yingkui Li

Subjects

010506 paleontology, geography, geography.geographical_feature_category, Plateau, Glacial landform, Geography, Planning and Development, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, U-shaped valley, Moraine, Tributary, Earth and Planetary Sciences (miscellaneous), Glacial period, Geomorphology, Geology, Terminal moraine, 0105 earth and related environmental sciences

Abstract

We present a glacial geomorphological map (1:825,000) of the Parlung Zangbo Valley in the southeastern Tibetan Plateau based on Google Earth imagery and the 30 m ASTER Global Digital Elevation Model (ASTER GDEM). The mapped region covers 2.9 × 104 km2, including abundant glacial landforms such as glacial valleys, marginal moraines (including terminal moraines and lateral moraines), and hummocky moraines. Glacial valleys are distributed mainly above 2100 m a.s.l. with lengths from 1 to 130 km. Multiple marginal moraines occur along the glacial valleys, indicating the presence of multiple glacial events. The lowest moraines are distributed mainly at the mouth of each valley between 2400 and 4000 m a.s.l. Hummocky moraines are mainly distributed in the two main tributary valleys: the Bodui Zangbo Valley and the Yigong Zangbo Valley. One ice-dammed paleolake was mapped with a surface area of 12.5 km2. The mapped glacial features (including contemporary glaciers) cover 1.2 × 104 km2, about 40% of the mapped area, representing the minimum extent of maximum glaciation. This map provides a useful data set for reconstructing the timing and extent of paleoglaciations in this area.

Published

2015

19. Three-dimensional numerical simulation of glacial trough forming process

Author

Yaolin Shi and ShaoHua Yang

Subjects

Plucking, U-shaped valley, geography, geography.geographical_feature_category, Computer simulation, Erosion, General Earth and Planetary Sciences, Forming processes, Glacier, Numerical models, Geomorphology, Erosion rate, Geology

Abstract

The glacial trough is a common glacier erosion landscape, which plays an important role in the study of glacier erosion processes. In a sharp contrast with the developing river, which is generally meandering, the developing glacial trough is usually wide and straight. Is the straightness of the glacial trough just the special phenomenon of some areas or a universal feature? What controls the straightness of the glacial trough? Until now, these issues have not been studied yet. In this paper, we conduct systematic numerical models of the glacier erosion and simulate the erosion evolution process of the glacial trough. Numerical simulations show that: (1) while the meandering glacier is eroding deeper to form the U-shaped cross section, the glacier is eroding laterally. The erosion rate of the ice-facing slope is bigger than that of the back-slope. (2) The smaller (bigger) the slope is, the smaller (bigger) the glacier erosion intensity is. (3) The smaller (bigger) the ice discharge is, the smaller (bigger) the glacier erosion intensity is. In the glacier erosion process, the erosion rate of the ice-facing slope is always greater than that of the back-slope. Therefore, the glacial trough always develops into more straight form. This paper comes to the conclusion that the shape evolution of the glacial trough is controlled mainly by the erosion mechanism of the glacier. Thereby, the glacial trough prefers straight geometry.

Published

2015

20. Research history on glacial geomorphology and geochronology of the Cantabrian Mountains, north Iberia (43–42°N/7–2°W)

Author

Montserrat Jiménez-Sánchez, María José Domínguez-Cuesta, Laura Rodríguez-Rodríguez, and Arantza Aranburu

Subjects

Marine isotope stage, geography, geography.geographical_feature_category, Pleistocene, Glacial landform, Last Glacial Maximum, Glacier, U-shaped valley, Paleontology, Moraine, Glacial period, Geomorphology, Geology, Earth-Surface Processes

Abstract

The study of glacial geomorphology in the Cantabrian Mountains, a mountain range that extends 460 km along the northern coast of the Iberian Peninsula (SW Europe), started late in the 19th century and continues nowadays with a growing number of research papers. However, the number and timing of glaciations remains poorly understood, partially due to the still limited number of numerical ages. Its southerly location and proximity to the Atlantic Ocean make this mountain range potentially sensitive to past climate fluctuations. This work updates the glacial knowledge evolution for the whole range, from the Queixa-Invernadoiro Massif to the Basque Mountains, reviewing: (i) the history of glacial research since the late 19th century; (ii) the methodological approaches applied to reconstruct both the spatial extent and timing of past glacial stages; and (iii) the main geomorphological and geochronological evidence reported until date, including glacial features attributed to the Last Glacial Cycle (last 120 ka) and previous glaciations. According to current knowledge, glaciers extended over the Cantabrian Mountains covering a total area of 3150 km2, showing asymmetric development conditioned by variations of the topographic configuration and moisture supply along the range. Available geochronology based on radiocarbon, optically stimulated luminescence and terrestrial cosmogenic nuclides suggests the occurrence of at least 2 glacial advances during the Last Glacial Cycle: (i) a glacial maximum stage that took place at a minimum age of 36–45 ka (Marine Isotope Stage 3) and (ii) a second glacial advance at 19–23 ka (MIS 2). In some areas the extent of the glacier tongues during the second glacial advance was comparable to previous glacial maximum and was followed by glacial retreat conditions with formation of recessional moraines. Asynchronous glacial maximum conditions have been reported only for the Castro Valnera (MIS 4, 3 numerical ages) and Queixa-Invernadoiro (MIS 6, 1 numerical age) massifs until now. Finally, geomorphological evidence reported in Picos de Europa has been attributed to prior glaciations and correlated to cold conditions recorded during MIS 12 and MIS 22 based on a very limited number of numerical ages.

Published

2015

21. Quaternary glaciations and glacial landform evolution in the Tailan River valley, Tianshan Range, China

Author

Jingdong Zhao, Yunfei Wu, Jonathan M. Harbor, Xiufeng Yin, Jie Wang, and Shiyin Liu

Subjects

Marine isotope stage, geography, geography.geographical_feature_category, Glacial landform, Glacier, Paleontology, U-shaped valley, Moraine, Glacial period, Neoglaciation, Geomorphology, Geology, Holocene, Earth-Surface Processes

Abstract

The Tailan River originates on the southern slope of Tumur Peak, the largest center of modern glaciation in the Tianshan Range. Five moraine complexes and associated fluvioglacial deposits in this valley record a complex history of Quaternary glacial cycles and landform evolution. Electron spin resonance (ESR) dating of glacial sediments was carried out using germanium (Ge) centers in quartz grains, which are sensitive to both sunlight and grinding. Based on the dating results as well as geomorphic and stratigraphic data, the Piyazilike end moraines (the second moraine complex) were deposited during Neoglaciation (the largest glacial advances during the last 3–4 ka in western China) and an early Holocene glacial advance, the third set of moraines was deposited in marine isotope stage (MIS) 2–4, and the glacial landforms of the Tailan glaciation (the fourth moraine complex), which include hummocky moraines on the piedmont, were formed in MIS 6 (penultimate glaciation). The end moraines of the innermost moraine complex (the first moraine complex) are inferred to have been deposited during the Little Ice Age (LIA). Thus the landforms and dates indicate compound valley glaciers from the LIA to MIS 2–4, and piedmont glaciers during MIS 6. The oldest tills studied belong to the “Kokdepsang Glacial Stage”, and occur on a high plateau. Based on similar glacial landforms (glacial deposits on a high plateau and a high glacial terrace) and their ESR ages in adjacent valleys on the southern slope of Tumur Peak, the Kokdepsang Glacial Stage is assigned to MIS 12.

Published

2015

22. Late Holocene Glacier Dynamics in the Miyar Basin, Lahaul Himalaya, India

Author

Pritam Chand, Ajai, Sanjay Deswal, Rakesh Saini, Milap Chand Sharma, Pradeep Srivastava, Navin Juyal, Ishwar Singh, and I. M. Bahuguna

Subjects

010506 paleontology, 010504 meteorology & atmospheric sciences, glaciation, 01 natural sciences, Paleontology, Paraglacial, Younger Dryas, Glacial period, OSL, Geomorphology, Terminal moraine, Holocene, 0105 earth and related environmental sciences, geography, Lahaul Himalaya, LGM, ELA, geography.geographical_feature_category, lcsh:QE1-996.5, Last Glacial Maximum, Glacier, lcsh:Geology, U-shaped valley, General Earth and Planetary Sciences, Geology

Abstract

Detailed field mapping of glacial and paraglacial landforms and optical dating from these landforms are used to reconstruct the early Holocene glaciation in the semi-arid region of Miyar basin, Lahaul Himalaya. The study identifies three stages of glaciation, of decreasing magnitude and termed, from oldest to youngest, the Miyar stage (MR-I), Khanjar stage (KH-II), and Menthosa advance (M-III). The oldest glacial stage (MR-I) has been established on the basis of detailed geomorphological evidence such as U-shaped valley morphology, trimlines, and truncated spurs. It is speculated to be older than the global Last Glacial Maximum (gLGM) based on the magnitude of ΔELA (Equilibrium-Line Altitude, 606m). No evidence of glacier expansion recorded from the basin correlates with the period of the gLGM. The second stage (KH-II) is well represented by extensive depositional features such as lateral and terminal moraines, drumlins, and lacustrine fills that have been constrained within 10 ± 1 to 6.6 ± 1.0 ka (Optically stimulated luminescence—OSL—ages), dating it to the early Holocene advance following the Younger Dryas cooling event. Exceptionally young glacial records of expansion are limited within a few hundred meters of the present termini of tributary glaciers and correlates with the 18th-century cooling event. Records of this glacial advance, termed the Menthosa advance, are clearly noticed in some tributary valleys.

Published

2017

23. Regional mid-Pleistocene glaciation in central Patagonia

Author

Sheng Xu, Christopher M. Darvill, Frédéric Herman, Marcus Christl, Kevin Norton, Tibor J. Dunai, Ángel Rodés, Antoine Cogez, Andrew S. Hein, Monika Mendelova, and Michael R. Kaplan

Subjects

Archeology, 010504 meteorology & atmospheric sciences, Pleistocene, Moraine degradation, Cosmogenic nuclide surface exposure dating, Beryllium-10, 010502 geochemistry & geophysics, 01 natural sciences, Paleontology, Glacial period, Marine isotope stage 8, Moraine boulders, Geomorphology, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Global and Planetary Change, geography, geography.geographical_feature_category, Last Glacial Maximum, Glacial chronology, Geology, Glacier, U-shaped valley, Moraine, Outwash plain, Ice sheet

Abstract

Southern South America contains a glacial geomorphological record that spans the past million years and has the potential to provide palaeoclimate information for several glacial periods in Earth's history. In central Patagonia, two major outlet glaciers of the former Patagonian Ice Sheet carved deep basins ∼50 km wide and extending over 100 km into the Andean plain east of the mountain front. A succession of nested glacial moraines offers the possibility of determining when the ice lobes advanced and whether such advances occurred synchronously. The existing chronology, which was obtained using different methods in each valley, indicates the penultimate moraines differ in age by a full glacial cycle. Here, we test this hypothesis further using a uniform methodology that combines cosmogenic nuclide ages from moraine boulders, moraine cobbles and outwash cobbles. 10 Be concentrations in eighteen outwash cobbles from the Moreno outwash terrace in the Lago Buenos Aires valley yield surface exposure ages of 169–269 ka. We find 10 Be inheritance is low and therefore use the oldest surface cobbles to date the deposit at 260–270 ka, which is indistinguishable from the age obtained in the neighbouring Lago Pueyrredon valley. This suggests a regionally significant glaciation during Marine Isotope Stage 8, and broad interhemispheric synchrony of glacial maxima during the mid to late Pleistocene. Finally, we find the dated outwash terrace is 70–100 ka older than the associated moraines. On the basis of geomorphological observations, we suggest this difference can be explained by exhumation of moraine boulders.

Published

2017

24. Relict glacial landscape in the Sierra Baguales Mountain Range (50°-51° S): evidence of glaciation dynamics and types in the eastern foothills of the southern Patagonian Andes

Author

José Araos, Jacobus Philiphus Le Roux, and Néstor M. Gutiérrez

Subjects

010506 paleontology, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geography, Planning and Development, Ice field, Geology, Glacier, Last Glacial Maximum, Glacier morphology, 01 natural sciences, U-shaped valley, Deglaciation, Glacial period, Physical geography, Ice sheet, Geomorphology, 0105 earth and related environmental sciences, Nature and Landscape Conservation, Earth-Surface Processes

Abstract

The glacial morphology of southern South American presents invaluable evidence to reconstruct former glacier behaviour and its relation to climate and environmental changes. However, there are still spatial and temporal gaps in the reconstruction of the Holocene Patagonian glacial landscape. Here we present the first geomorphological record for the Sierra Baguales Mountain Range (SBMR), forming the eastern foothills of the Southern Patagonian Andes 200 km from the Pacific coast. This area is topographically isolated from the Southern Patagonian Ice Field (SPIF), and is affected by the Westerly Winds. The study area shows evidence of ice sheet and alpine glaciations related to Andean uplift, which caused a marked climatic contrast between its western and eastern flanks since the Last Glacial Maximum (LGM). The regional rock mass strength and precipitation gradient acted as a controlling factor in the glacial cirque distribution and sizes, as well as in the development of glaciation types. We report new radiocarbon dates associated with warm/dry to cold/wet climatic changes during the middle Holocene, when former small alpine glaciers were located in the uppermost section of the SBMR basins, and eventually converged to form a small ice field or a composite valley glacier at lower elevations. This can be explained by an estimated regional temperature drop of 3.8°C±0.8°C, based on a 585±26 m Equilibrium Line Altitude (ELA) descent, inferred by geomorphological evidence and the Accumulation Area Ratio (AAR), in addition to a free-air adiabatic lapse rate. Subsequently, the glaciers receded due to climatic factors including a rise in temperature, as well as non-climatic factors, mainly the glacier bedrock topography.

Published

2017

25. About this title ‐ Quaternary Glaciation in the Mediterranean Mountains

Author

Philip D. Hughes and Jamie Woodward

Subjects

geography, geography.geographical_feature_category, Pleistocene, Geology, Ocean Engineering, Glacier, U-shaped valley, Marinoan glaciation, Climatology, Ice age, Wisconsin glaciation, Physical geography, Glacial period, Bull Lake glaciation, Water Science and Technology

Abstract

The mountains of the Mediterranean world are now largely ice free, but many were repeatedly glaciated during the Quaternary ice age. This created spectacular glaciated landscapes with a rich array of glacial deposits and landforms. The glacial and glacio-fluvial records are often very well preserved and our understanding of the timing of Quaternary glaciation has very recently been transformed through the application of dating methods utilizing uranium-series and cosmogenic isotopes. Glacial records from the Mediterranean now boast some of the most robust chronologies for mountain glaciation anywhere in the world – they represent a unique archive of Quaternary environmental change of global significance. The southerly latitude and relatively small size of Mediterranean glaciers rendered them especially sensitive to Pleistocene and Holocene climate changes. This volume brings together the leading researchers and the latest research on Mediterranean glaciation. Several papers also explore glacier behaviour in the Holocene – including those glaciers of southernmost Europe at risk of disappearing this century.

Published

2017

26. Glaciations and Climate Change

Author

Paul W. Williams

Subjects

Antarctic Cold Reversal, U-shaped valley, geography, geography.geographical_feature_category, Climatology, Interglacial, Ice age, Last Glacial Maximum, Glacier, Glacial period, Physical geography, Herbfield, Geology

Abstract

The Quaternary ice age in New Zealand has similarities to and contrasts with glacial events in the Northern Hemisphere. During the Last Glacial Cycle, the largest glacial advance in New Zealand was 67–62,000 years ago, and so not during the conventional global Last Glacial Maximum (gLGM). In New Zealand glacials were characterised by alpine glacier expansion, mainly in South Island. In central North Island there were small glaciers, periglacial activity and large expanses of herbfield and shrubland. Tall podocarp-broadleaf forest retreated to Northland. The gLGM in New Zealand occurred 32–26,000 years ago, at least 12,000 years before the ice volume reached its maximum in the Northern Hemisphere, and by the time that occurred (19–18,000 years ago) New Zealand glaciers had retreated and almost disappeared from lower valleys.

Published

2017

27. Modelling the diversion of erratic boulders by the Valais Glacier during the last glacial maximum

Author

Guillaume Jouvet, Martin Funk, Susan Ivy-Ochs, and Julien Seguinot

Subjects

Geomorphology, ice-sheet modelling, paleoclimate, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ice stream, Glacier, Last Glacial Maximum, 010502 geochemistry & geophysics, 01 natural sciences, Ice-sheet model, U-shaped valley, Paleoclimatology, Precipitation, Ice sheet, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

In this study, a modelling approach was used to investigate the cause of the diversion of erratic boulders from Mont Blanc and southern Valais by the Valais Glacier to the Solothurn lobe during the Last Glacial Maximum (LGM). Using the Parallel Ice Sheet Model, we simulated the ice flow field during the LGM, and analyzed the trajectories taken by erratic boulders from areas with characteristic lithologies. The main difficulty in this exercise laid with the large uncertainties affecting the paleo climate forcing required as input for the surface mass-balance model. In order to mimic the prevailing climate conditions during the LGM, we applied different temperature offsets and regional precipitation corrections to present-day climate data, and selected the parametrizations, which yielded the best match between the modelled ice extent and the geomorphologically-based ice-margin reconstruction. After running a range of simulations with varying parameters, our results showed that only one parametrization allowed boulders to be diverted to the Solothurn lobe during the LGM. This precipitation pattern supports the existing theory of preferential southwesterly advection of moisture to the alps during the LGM, but also indicates strongly enhanced precipitation over the Mont Blanc massif and enhanced cooling over the Jura Mountains., Journal of Glaciology, 63 (239), ISSN:0022-1430, ISSN:1727-5652

Published

2017

28. New glacial evidences at the Talacasto paleofjord (Paganzo basin, W-Argentina) and its implications for the paleogeography of the Gondwana margin

Author

Juan Pablo Milana, Ubiratan Ferrucio Faccini, and Carolina Danielski Aquino

Subjects

geography, geography.geographical_feature_category, Outcrop, Geology, Glacier, Sedimentary depositional environment, U-shaped valley, Paleontology, Deglaciation, Glacial period, Meltwater, Paleocurrent, Earth-Surface Processes

Abstract

The Talacasto paleovalley is situated in the Central Precordillera of San Juan, Argentina, where upper Carboniferous-Permian rocks (Paganzo Group) rest on Devonian sandstones of the Punta Negra Formation. This outcrop is an excellent example of a glacial valley-fill sequence that records at least two high-frequency cycles of the advance and retreat of a glacier into the valley. The paleocurrent analysis shows transport predominantly to the south, indicating that at this site the ice flow differs from the other nearby paleovalleys. Evidence of the glacial origin of this valley can be seen in the glacial striae on the valley's sides, as well as the U-shape of the valley, indicated by very steep locally overhanging valley walls. Deglaciation is indicated by a set of retransported conglomerates deposited in a shallow-water environment followed by a transgressive succession, which suggests eustatic rise due to meltwater input to the paleofjord. The complete sedimentary succession records distinct stages in the evolution of the valley-fill, represented by seven stratigraphical units. These units are identified based on facies associations and their interpreted depositional setting. Units 1 to 5 show one cycle of deglaciation and unit 6 marks the beginning of a new cycle of glacier advance which is characterized by different types of glacial deposits. All units show evidence of glacial influence such as dropstones and striated clasts, which indicates that the glaciers were always present in the valley or in adjacent areas during sedimentation. The Talacasto paleofjord provides good evidence of the Late Paleozoic Gondwana glaciation in western Argentina and examples of sedimentary successions which have been interpreted as being deposited by a confined wet-based glacier in advance and retreat cycles, with eventual release of icebergs into the basin. The outcrop is also a key for reconstructing the local glacial paleogeography, and it suggests a new interpretation that is not in agreement with previous studies. Finally, the importance of the Talacasto paleovalley for the Paganzo basin lies in its orientation, because it allows the reconstruction of the ice paleoflow and indication, for the first time, that marine ingressions into this area were not taking place along the Jachal trough, as expected, but along a different connection to the sea, which for this work we will call the San Juan Paleotrough.

Published

2014

29. Glacier advances in northeastern Turkey before and during the global Last Glacial Maximum

Author

Naki Akçar, Regina Reber, Christian Schlüchter, Peter W. Kubik, Dmitry Tikhomirov, Vural Yavuz, and Serdar Yeşilyurt

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, Tidewater glacier cycle, Rock glacier, Geology, Glacier, Cirque glacier, U-shaped valley, Glacier mass balance, Moraine, 550 Earth sciences & geology, Physical geography, Geomorphology, Ecology, Evolution, Behavior and Systematics, Terminal moraine

Abstract

Our study in the Başyayla Valley in northeastern Anatolia showed evidence of four glacier advances that built terminal and lateral moraines. Surface exposure dating of boulders on these moraines showed that the Maximum Ice Extent (MIE) was asynchronous with the global Last Glacial Maximum (LGM; 22.1 ± 4.3 thousand years; ka). The local {MIE} took place at least 57.0 ± 3.5 ka ago. The extent of the Başyayla Glacier during this advance is not known exactly because the boulders are only preserved on a lateral moraine. The next advance was prior to 41.5 ± 2.5 ka, and it descended down the valley to approximately 2320 m above sea level (m a.s.l.), with a glacier length of 5.3 km. During the early global LGM, the Başyayla Glacier extended for a distance of 4.9 km down to approx. 2430 m a.s.l. The last recorded advance occurred during the global LGM. This extension was 0.7 km smaller than the local {MIE} and its terminus reached 2490 m a.s.l. only. The exposure ages of boulders in a retreat position at an altitude of approx. 3045 m a.s.l. indicate that the valley has remained ice-free since the Lateglacial period. Therefore, the Lateglacial extent was limited to the cirque system in the uppermost part of the catchment. Furthermore, Holocene glacier oscillations seem to be either absent or restricted to solifluction in the whole catchment and to rock glacier movements in the southern tributary of the Başyayla Valley system.

Published

2014

30. Late Quaternary glacial advances in the Tons River Valley, Garhwal Himalaya, India and regional synchronicity

Author

Zahid Majeed, Manish Mehta, Bhanu Pratap, Pradeep Srivastava, D. P. Dobhal, and Anil K. Gupta

Subjects

Archeology, Global and Planetary Change, River valley, geography, geography.geographical_feature_category, Ecology, Paleontology, Glacier, Lower temperature, U-shaped valley, Equilibrium line altitude, Moraine, Physical geography, Glacial period, Quaternary, Geomorphology, Geology, Earth-Surface Processes

Abstract

The glacial history of the Tons River Valley reveals significant changes in the glacier extent during the late Quaternary driven by regional and global climatic changes. The successions of moraines in glaciated valley of the upper Tons River, Garhwal Himalaya, provide evidence of at least five glacial advances during the late Quaternary Period. This study discusses about the synchronicity of Himalayan glaciers and comparison between results of Optically Stimulated Luminescence (OSL) and Cosmogenic Radio Nuclide (CRN 10Be) dates. The OSL dates of moraine sediments deposited by glacier in the upper Tons valley show parallelism with the ages deduced from the CRN of 10Be by Scherler et al. in the same area. The five episodes of glacier advances are dated at 20 ± 3, 16 ± 2, 8 ± 1.2, 6 ± 0.7 and 3 ± 0.6 kyr (between Marine Isotope Stages (MISs) I and II). Two of the more extensive phases of glaciation were during the early and later parts of MIS II, which attributed to the lower temperature and enhanced the mid-latitude westerlies. During the periods between 20 ± 3 kyr and present day, the glacier lost ~47 km2 (33%) area, 0.88 × 1010 m3 water equivalent (w.e.) volume with the rate of 0.44 × 106 m3 w.e./yr, which is close to the current melting rates of Central Himalayan glaciers. The estimation of equilibrium line altitude (ELA) using these dates and geomorphic data suggests a vertical shift of ~451 m for Jaundhar Glacier and ~598 m for Bandarpunch Glacier since 20 kyr. The results from Tons valley glaciation show synchronicity with the records of glacial advancements from the other Himalayan glacier valleys. These data allow testing of two widely used dating techniques and importance of global climate change and monsoon influence on glaciation in the Himalaya.

Published

2014

31. Subglacial sediment, proglacial lake-level and topographic controls on ice extent and lobe geometries during the Last Glacial Maximum in NW Russia

Author

E. Larsen, Astrid Lyså, Dmitry Subetto, Ola Fredin, Denis A. Kuznetsov, and Maria Jensen

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, Ice stream, Geology, Glacier, Glacier morphology, U-shaped valley, Ice tongue, Deglaciation, Glacial period, Ice sheet, Geomorphology, Ecology, Evolution, Behavior and Systematics

Abstract

Investigations in sections along the rivers Severnaya Dvina and Vaga, and morphological mapping based on a new digital elevation model and Landsat imagery, allow for a reinterpretation of the extent of the Scandinavian Ice Sheet during the Last Glacial Maximum (LGM). The reconstruction provides a much better link between stratigraphical and morphological expression of glaciation than previous proposals. Most striking is the configuration of long, low-gradient ice-lobes (ice-streams) extending for some 300–400 km up the wide and smooth river valleys. Their extremely low surface gradients are evidenced by glacial trimlines that formed along the sides of the ice-lobes in contact with the gentle valley slopes. In the main valleys, end moraines marking terminal positions are present, whereas drumlins are rare in the peripheral areas of the ice sheet but found in some tributary valleys at somewhat higher elevations. Large drumlin fields, however, are found farther up-ice. The glacial sediment succession is composed of waterlain sediments and tills. The sediments provide evidence of distal ice damming, glacier overriding and retreat, and finally distally glaciolacustrine sedimentation and lake drainage. The diamicton unit associated with the LGM shows evidence of basal coupling, although more striking is the abundant evidence for ice–bed decoupling. These include in situ waterlain sediments within tills, and clastic sills running along the till/substrate contact showing lift-off. These features indicate that the weight of the glacier lobes was, to a large extent, carried by pore-water pressure in subglacial sediments, and that subglacial shear and erosion were moderate. Thus, fast ice flow in the lobes is envisaged. The balance between glacier weight and pore-water pressure was probably maintained over time by the buoyancy effect of glaciers advancing into proglacial lakes. Subglacial lakes may have formed by capture of proglacial lakes during glacial advance. The combination of low-gradient ice and decoupled beds indicate that glacier advance and extent was largely controlled by lake levels and topographic thresholds. This is taken to indicate that steeper-gradient ice much farther upstream was providing the gravitational push. A presumably abrupt change in ice-surface profile is supported by the mapped distribution of glacial bedforms. The model presented herein potentially has wide applicability for large parts of northern Russia as the topographic setting and glacier advance in lakes across fine-grained low-permeable sediments provide very similar conditions.

Published

2014

32. Timing of glacier fluctuations and trigger mechanisms in eastern Qinghai–Tibetan Plateau during the late Quaternary

Author

LanHua Zeng, Zhongping Lai, Shangzhe Zhou, and Xianjiao Ou

Subjects

010506 paleontology, geography, Plateau, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Last Glacial Maximum, Glacier, 01 natural sciences, U-shaped valley, Arts and Humanities (miscellaneous), Moraine, Climatology, General Earth and Planetary Sciences, Physical geography, Glacial period, Quaternary, Holocene, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

It is highly debated whether glacial advances on the Qinghai–Tibetan Plateau (QTP) occurred as a response to temperature cooling, or whether they were forced by an increase in moisture brought by the intensive Indian summer monsoon. We here report a case study investigating this issue. Multiple moraine series in the Yingpu Valley, Queer Shan ranges of the Hengduan Mountains, and eastern QTP, provide an excellent archive for examining the timing and trigger mechanism of glacier fluctuations. Twenty-seven optically stimulated luminescence (OSL) samples of glacial sediments were collected from this valley. The quartz OSL ages show that the moraine series of Y-1, I, M and O were formed during the Late Holocene, Late Glacial, the global Last Glacial Maximum (LGM) and Marine Oxygen Isotope Stage (MIS) 3 (likely mid-MIS-3). The youngest Y-2 moraines probably formed during the Little Ice Age (LIA). The oldest H moraines formed before MIS-3. We found that glacial advances during the late Quaternary at the Yingpu Valley responded to cold stages or cold events rather than episodes of enhanced summer monsoon and moisture. As a result, glaciers in the monsoonal Hengduan Mountains were mainly triggered by changes in temperature. Millennial time scale temperature oscillations might have caused the multiple glacial advances.

Published

2014

33. Subglacial extensional fracture development and implications for Alpine Valley evolution

Author

Kerry Leith, Simon Loew, Jeffrey R. Moore, and Florian Amann

Subjects

geography, geography.geographical_feature_category, Bedrock, Glacier, Crust, Tectonics, U-shaped valley, Geophysics, Interglacial, Erosion, Glacial period, Geomorphology, Geology, Earth-Surface Processes

Abstract

[1] Bedrock stresses induced through exhumation and tectonic processes play a key role in the topographic evolution of alpine valleys. Using a finite difference model combining the effects of tectonics, erosion, and long-term bedrock strength, we assess the development of near-surface in situ stresses and predict bedrock behavior in response to glacial erosion in an Alpine Valley (the Matter Valley, southern Switzerland). Initial stresses are derived from the regional tectonic history, which is characterized by ongoing transtensional or extensional strain throughout exhumation of the brittle crust. We find that bedrock stresses beneath glacial ice in an initial V-shaped topography are sufficient to induce localized extensional fracturing in a zone extending laterally 600 m from the valley axis. The limit of this zone is reflected in the landscape today by a valley “shoulder,” separating linear upper mountain slopes from the deep U-shaped inner valley. We propose that this extensional fracture development enhanced glacial quarrying between the valley shoulder and axis and identify a positive feedback where enhanced quarrying promoted valley incision, which in turn increased in situ stress concentrations near the valley floor, assisting erosion and further driving rapid U-shaped valley development. During interglacial periods, these stresses were relieved through brittle strain or topographic modification, and without significant erosion to reach more highly stressed bedrock, subsequent glaciation caused a reduction in differential stress and suppressed extensional fracturing. A combination of stress relief during interglacial periods, and increased ice accumulation rates in highly incised valleys, will reduce the likelihood of repeat enhanced erosion events.

Published

2014

34. Chronology and climatic implications of Late Quaternary glaciations in the Goriganga valley, central Himalaya, India

Author

S. Nawaz Ali, Anil D. Shukla, R.H. Biswas, and Navin Juyal

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, Geology, Westerlies, Glacier, Last Glacial Maximum, U-shaped valley, Moraine, Deglaciation, Physical geography, Glacial period, Quaternary, Geomorphology, Ecology, Evolution, Behavior and Systematics

Abstract

Goriganga valley, which is located in the transition zone between the dry steppe of the Tibetan plateau in the north and the sub-humid Himalayan climate in the south, has preserved four events of glaciation with decreasing magnitude. The oldest Stage-I glaciation is represented by a ∼12.5 km long discontinuous diamictite ridge which terminates north of Rilkot (∼3100 m asl). The Stage-II glaciation is represented by sub-rounded and partially eroded lateral moraines and terminates around Martoli village (∼3240 m asl). The Stage-III and IV glacial moraines are sharp crested, unstable and terminate proximal to the present day glacier at ∼3640 m asl and ∼3740 m asl respectively. The Stage-II moraines have been optically dated between 25 ± 2 ka and 22 ± 1 ka implying that glacier expanded during the global Last Glacial Maximum (LGM). This is contrary to the suggestion that during Last Glacial maximum (LGM) glaciation was limited in extent due to weak Indian Summer Monsoon (ISM) in the monsoon dominated regions of the Himalaya. We ascribe the LGM glaciations to a combination of the lowered temperature and enhanced mid-latitude westerlies. Following the LGM glaciation, Goriganga valley experienced two major pulses of deglaciation. The older event is dated between 16 and 12 ka and is coeval with the initiation of the ISM whereas the younger events (10−8 ka) represent the early to mid-Holocene strengthened ISM. The Stage-III and IV glaciations which terminated proximal to the modern glacier are speculated to occur during the mid-Holocene and Little Ice Age (LIA) respectively.

Published

2013

35. Late Quaternary glaciation in the Nun-Kun massif, northwestern India

Author

Hyoun Soo Lim, Ho Il Yoon, Kyu-Cheul Yoo, Lewis A. Owen, Yeong Bae Seong, Madhav K. Murari, and Su Young Lee

Subjects

Archeology, geography, geography.geographical_feature_category, Glacial landform, Geology, Glacier, U-shaped valley, Moraine, Abrupt climate change, Glacial period, Physical geography, Geomorphology, Ecology, Evolution, Behavior and Systematics, Terminal moraine, Holocene

Abstract

The late Quaternary glacial history of the Nun-Kun massif, located on the boundary between the Greater Himalaya and the Zanskar range in northwestern India, was reconstructed. On the basis of morphostratigraphy and 10Be dating of glacial landforms (moraines and glacial trimlines), five glacial stages were recognized and defined, namely: (i) the Achambur glacial stage dated to Marine Oxygen Isotope Stage 3 to 4 (38.7–62.7 ka); (ii) the Tongul glacial stage dated to the early part of the Lateglacial (16.7–17.4 ka); (iii) the Amantick glacial stage dated to the later part of the Lateglacial (14.3 ka, 11.7–12.4 ka); (iv) the Lomp glacial stage dated to the Little Ice Age; and (v) the Tanak glacial stage, which has the youngest moraines, probably dating to the last few decades or so. Present and former equilibrium-line altitudes (ELAs) were calculated using the standard area accumulation ratio method. The average present-day ELA of ∼4790 m above sea level in the Greater Himalaya is lower than those in the Ladakh and Zanskar ranges, namely 5380 and ∼5900 m a.s.l., respectively. The ELA in the Zanskar range is higher than in the Ladakh range, possibly due to the higher peaks in the Ladakh range that are able to more effectively capture and store snow and ice. ELA depressions decrease towards the Ladakh range (i.e. inner Plateau). Peat beds interbedded with aeolian deposits that cap the terminal moraine of Tarangoz Glacier suggest millennial-time-scale climate change throughout the Holocene, with soil formation times at c. 1.5, c. 3.4 and c. 5.2 ka, probably coinciding with Holocene abrupt climate change events. Given the style and timing of glaciation in the study area, it is likely that climate in the Nun-Kun region is linked to Northern Hemisphere climate oscillations with teleconnections via the mid-latitude westerlies.

Published

2013

36. Chronology of late Quaternary glaciation in the Pindar valley, Alaknanda basin, Central Himalaya (India)

Author

Saurabh Kumar Rastogi, Rameshwar Bali, Pradeep Srivastava, K. K. Agarwal, S. Nawaz Ali, and Kalyan Krishna

Subjects

geography, geography.geographical_feature_category, Geology, Glacier, Paleontology, U-shaped valley, Marinoan glaciation, Moraine, Glacial period, Quaternary, Geomorphology, Terminal moraine, Holocene, Earth-Surface Processes

Abstract

Palaeoglacial reconstruction based on geomorphological mapping in the Pindari glacier valley, Alaknanda basin (Central Himalaya), has revealed five glacial stages with decreasing magnitude. The oldest and most extensive stage-I glaciation deposited sediments at ∼2200 masl (Khati village). The stage-II glaciation was around 7 km long and luminescence dated to 25 ± 2 ka, and has deposits at 3200 masl (Phurkia village). Stage-III glaciation is represented by degraded linear moraine ridges and is dated to 6 ± 1 ka and its remnants can be found around 3850 masl. A sharp crested crescentic moraine extending from around 3650 masl to 3900 masl is attributed to stage-IV glaciation and is dated to 3 ± 1 ka. Following this, there appears to have been a gradual recession in Pindari glacier as indicated by four sharp crested unconsolidated moraines (stage-V) on the valley floor which abuts the stage-IV moraine. We suggest that the stage-I glaciation occurred during the cool and wet Marine Isotopic Stage 3/4 (MIS-3/4), stage-II glaciations began with the onset of MIS-2, whereas the stage-III and IV glaciations occurred during the mid-to late Holocene (MIS-1). We speculate that the first sharp crested unconsolidated moraines around 3600 masl correspond to the later phase of the Little Ice Age (LIA). Historical data suggests that the remaining three ridges represent Pindari glacier snout positions at 1906, 1958 and 1965. We argue that the late Quaternary glaciations in the Pindar valley were modulated by changing insolation and summer monsoon intensity including the LIA, whereas the 20th century recessional trends can be attributed to post-LIA warming.

Published

2013

37. Glacial and fluvial deposits in the aragón valley, central‐western pyrenees: chronology of the pyrenean late pleistocene glaciers

Author

Edward J. Rhodes, Blas L. Valero-Garcés, Carlos Sancho, C. Martí-Bono, Ana Moreno, Penélope González-Sampériz, José María García-Ruiz, and José Luis Peña-Monné

Subjects

010506 paleontology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Pleistocene, Geography, Planning and Development, Fluvial, Geology, Glacier, 01 natural sciences, U-shaped valley, Paleontology, Moraine, Glacial period, Alley, Geomorphology, 0105 earth and related environmental sciences, Chronology

Abstract

33 páginas, 9 figuras.- Versión pre-print, [EN] The Aragón Valley glacier (Central Western Pyrenees) has been studied since the late nineteenth century and has become one of the best areas in the Pyrenees to study the occurrence of Pleistocene glaciations and the relationships between moraines and fluvial terraces. New morphological studies and absolute ages for moraines and fluvial terraces in the Aragón Valley allow a correlation with other Pyrenean glaciers and provide solid chronologies about the asynchroneity between global last glacial maximum (LGM) and the maximum ice extent (MIE). Six frontal arcs and three lateral morainic ridges were identified in the Villanúa basin terminal glacial complex. The main moraines (M1 and M2) correspond to two glacial stages (oxygen isotopic stages MIS 6 and MIS 4), dated at 171±22ka and 68±7ka, respectively. From a topographical point of view, moraine M1 appears to be linked to the 60m fluvioglacial terrace, dated in a tributary of the Aragón River at 263±21ka. The difference in age between M1 moraine and the 60m fluvioglacial terrace suggests that the latter belongs to an earlier glacial stage (MIS 8). Moraine M2 was clearly linked to the fluvioglacial 20m terrace. Other minor internal moraines were related to the 7-8m terrace. The dates obtained for the last glacial cycle (20-18ka) are similar to other chronologies for Mediterranean mountains, and confirm the occurrence of an early MIE in the Central Pyrenees that does not coincide with the global LGM. © 2012 Swedish Society for Anthropology and Geography., Support for this research was provided by the projects CALIBRE-LIMNOCAL (CGL2006-13327-C04-01) and GRACCIE-CONSOLIDER (CSD2007-00067), financed by the Spanish Inter-Ministry Commission of Science and Technology; and PIRINEOS ABRUPT (PM073/2007), financed by the Diputación General de Aragón. Additional funding was provided by the Spanish National Parks Agency through the project “Evolución climática y ambiental del Parque Nacional Picos de Europa desde el ultimo máximo glaciar” (ref. 53/2006), provided by the Spanish Ministry of Environment. The authors gratefully acknowledge Dr P.D. Hughes and an anonymous reviewer for their comments and suggestions, which significantly improve this paper.

Published

2013

38. Late Quaternary glaciations and connections to the piedmont plain in the prealpine environment: The middle and lower Astico Valley (NE Italy)

Author

Sandro Rossato, Giovanni Monegato, Barbara Gaudioso, Paolo Mozzi, Antonella Miola, and Maurizio Cucato

Subjects

geography, geography.geographical_feature_category, Pleistocene, Alluvial fan, Venetian Prealps, Glacier, LGM, Archaeology, alluvial fan, Paleontology, U-shaped valley, Pleistocene glaciations, Outwash plain, Glacial period, Chronostratigraphy, Quaternary, Geology, Earth-Surface Processes

Abstract

This work concerns the Late Quaternary evolution of the Astico Valley, with a focus on the relations between the glacial complexes hosted in the terminal valley tract and the piedmont fans. Three distinct glacial events are considered in this paper. Remote sensing, field survey, stratigraphic measurements and reconstructions, sand petrography, radiocarbon dating and pollen analyses allowed attribution of the last one to the LGM, a previous one probably to MIS 6 and the oldest to a generic glaciation of the Middle Pleistocene. Sand petrography analyses show that all these glacial deposits contain rock fragments that reached the Astico Valley through a transfluence of the Adige glacier. During LGM, this glacial stream entered the Astico Valley from the north through the Carbonare saddle (1075 m a.s.l.), as probably happened in previous major glaciations. The chronostratigraphy of two cores drilled near the towns of Vicenza and Villaverla shows that the outwash stream changed its route to the piedmont plain at the end of LGM, as a response to rapid glacial collapse. This switch led to the deactivation of the northwestern sector of the plain (Thiene fan) in favour of the southeastern one (Sandrigo fan). The lower and middle Astico Valley preserved significant evidence of even minor glacial fluctuations during the LGM in response to subtle climatic changes, namely an early glacial withdrawal at 23–24 cal ka, which may be difficult to distinguish in major Alpine glaciers.

Published

2013

39. Distribution of depth to ice-cemented soils in the high-elevation Quartermain Mountains, McMurdo Dry Valleys, Antarctica

Author

Gale Paulsen, Kris Zacny, Margarita M. Marinova, W. Andrew Jackson, Alfonso F. Davila, Denis Lacelle, Dale T. Andersen, Christopher P. McKay, Wayne H. Pollard, and Jennifer L. Heldmann

Subjects

geography, geography.geographical_feature_category, Climate change, Geology, Glacier, Albedo, Oceanography, Snow, Head (geology), U-shaped valley, High elevation, Soil water, Geomorphology, Ecology, Evolution, Behavior and Systematics

Abstract

We report on 475 measurements of depth to ice-cemented ground in four high-elevation valleys of the Quartermain Mountains, McMurdo Dry Valleys, Antarctica. These valleys have pervasive ice-cemented ground, and the depth to ice-cemented ground and the ice composition may be indicators of climate change. In University Valley, the measured depth to ice-cemented ground ranges from 0–98 cm. There is an overall trend of increasing depth to ice-cemented ground with distance from a small glacier at the head of the valley, with a slope of 32 cm depth per kilometre along the valley floor. For Farnell Valley, the depth to ice-cemented ground is roughly constant (c. 30 cm) in the upper and central parts of the valley, but increases sharply as the valley descends into Beacon Valley. The two valleys north of University Valley also have extensive ice-cemented ground, with depths of 20–40 cm, but exhibit no clear patterns of ice depth with location. For all valleys there is a tendency for the variability in depth to ice-cemented ground at a site to increase with increasing depth to ice. Snow recurrence, solar insolation, and surface albedo may all be factors that cause site to site variations in these valleys.

Published

2013

40. Glacial stages and post-glacial environmental evolution in the Upper Garonne valley, Central Pyrenees

Author

Marc Oliva, Maria Rosário Fernandes, Luis Felipe Dias Lopes, Pedro Palma, Jesús Ruiz-Fernández, and Repositório da Universidade de Lisboa

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Glacial landform, 010502 geochemistry & geophysics, 01 natural sciences, Deglaciation, Environmental Chemistry, Glacial period, Waste Management and Disposal, Geomorphology, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Holocene, Glacier, Glacier morphology, Pollution, U-shaped valley, Moraine, Last Glaciation, Wisconsin glaciation, Physical geography, Central Pyrenees, Upper Garonne, Geology

Abstract

The maximum glacial extent in the Central Pyrenees during the Last Glaciation is known to have occurred before the global Last Glacial Maximum, but the succession of cold events afterwards and their impact on the landscape are still relatively unknown. This study focuses on the environmental evolution in the upper valley of the Garonne River since the Last Glaciation. Geomorphological mapping allows analysis of the spatial distribution of inherited and current processes and landforms in the study area. The distribution of glacial records (moraines, till, erratic boulders, glacial thresholds) suggests the existence of four glacial stages, from the maximum expansion to the end of the glaciation. GIS modeling allows quantification of the Equilibrium Line Altitude, extent, thickness and volume of ice in each glacial stage. During the first stage, the Garonne glacier reached 460 m in the Loures-Barousse-Barbazan basin, where it formed a piedmont glacier 88 km from the head and extended over 960 km 2 . At a second stage of glacier stabilization during the deglaciation process, the valley glaciers were 12–23 km from the head until elevations of 1000–1850 m, covering an area of 157 km 2 . Glaciers during stage three remained isolated in the upper parts of the valley, at heights of 2050–2200 m and 2.6–4.5 km from the head, with a glacial surface of 16 km 2 . In stage four, cirque glaciers were formed between 2260 m and 2590 m, with a length of 0.4–2 km and a glacial area of 5.7 km 2 . Also, the wide range of periglacial, slope, nival and alluvial landforms existing in the formerly glaciated environments allows reconstruction of the post-glacial environmental dynamics in the upper Garonne basin. Today, the highest lands are organized following three elevation belts: subnival (1500–1900 m), nival (1900–2300 m) and periglacial/cryonival (2300–2800 m).

Published

2016

41. Differences in Bacterial Diversity and Communities Between Glacial Snow and Glacial Soil on the Chongce Ice Cap, West Kunlun Mountains

Author

Yong Qin Liu, Hao Xu, Shugui Hou, Guang li Yang, Ya Ping Liu, Wen Tao Du, Zhiguo Li, and Ri Le Baoge

Subjects

0301 basic medicine, geography, Multidisciplinary, geography.geographical_feature_category, Bacteria, Glacial landform, Biodiversity, Glacier, Snow, Article, 03 medical and health sciences, U-shaped valley, Soil, 030104 developmental biology, Rarefaction (ecology), Ecosystem, Ice Cover, Glacial period, Physical geography, Geology

Abstract

A detailed understanding of microbial ecology in different supraglacial habitats is important due to the unprecedented speed of glacier retreat. Differences in bacterial diversity and community structure between glacial snow and glacial soil on the Chongce Ice Cap were assessed using 454 pyrosequencing. Based on rarefaction curves, Chao1, ACE, and Shannon indices, we found that bacterial diversity in glacial snow was lower than that in glacial soil. Principal coordinate analysis (PCoA) and heatmap analysis indicated that there were major differences in bacterial communities between glacial snow and glacial soil. Most bacteria were different between the two habitats; however, there were some common bacteria shared between glacial snow and glacial soil. Some rare or functional bacterial resources were also present in the Chongce Ice Cap. These findings provide a preliminary understanding of the shifts in bacterial diversity and communities from glacial snow to glacial soil after the melting and inflow of glacial snow into glacial soil.

Published

2016

42. 10Be cosmic-ray exposure dating of moraines and rock avalanches in the Upper Romanche valley (French Alps): Evidence of two glacial advances during the Late Glacial/Holocene transition

Author

Vincent Rinterknecht, Fatima Mokadem, Melody Biette, Laëtitia Léanni, Marie Chenet, V. Robert, Daniel Brunstein, Erwan Roussel, Vincent Jomelli, Laboratoire de géographie physique : Environnements Quaternaires et Actuels (LGP), Université Paris 1 Panthéon-Sorbonne (UP1)-Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Géographie Physique et Environnementale (GEOLAB), Université Blaise Pascal - Clermont-Ferrand 2 (UBP)-Institut Sciences de l'Homme et de la Société (IR SHS UNILIM), Université de Limoges (UNILIM)-Université de Limoges (UNILIM)-Université Clermont Auvergne [2017-2020] (UCA [2017-2020])-Centre National de la Recherche Scientifique (CNRS)-Université Clermont Auvergne (UCA), Institut de Mécanique Céleste et de Calcul des Ephémérides (IMCCE), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Lille-Centre National de la Recherche Scientifique (CNRS), Institut Polytechnique des Sciences Avancées (IPSA), Centre européen de recherche et d'enseignement des géosciences de l'environnement (CEREGE), Institut de Recherche pour le Développement (IRD)-Institut National de la Recherche Agronomique (INRA)-Aix Marseille Université (AMU)-Collège de France (CdF (institution))-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique (CNRS)-Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Université Panthéon-Sorbonne (UP1), Centre National de la Recherche Scientifique (CNRS)-Institut Sciences de l'Homme et de la Société (IR SHS UNILIM), Université de Limoges (UNILIM)-Université de Limoges (UNILIM)-Université Blaise Pascal - Clermont-Ferrand 2 (UBP)-Université Clermont Auvergne (UCA), PSL Research University (PSL)-PSL Research University (PSL)-Université de Lille-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Collège de France (CdF)-Institut national des sciences de l'Univers (INSU - CNRS)-Aix Marseille Université (AMU)-Institut National de la Recherche Agronomique (INRA), Centre National de la Recherche Scientifique (CNRS)-Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Université Paris 1 Panthéon-Sorbonne (UP1), Université Blaise Pascal - Clermont-Ferrand 2 (UBP)-Université Clermont Auvergne [2017-2020] (UCA [2017-2020])-Université Clermont Auvergne (UCA)-Institut Sciences de l'Homme et de la Société (IR SHS UNILIM), Université de Limoges (UNILIM)-Université de Limoges (UNILIM)-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique (CNRS)-Université de Lille-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC), and Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Collège de France (CdF (institution))-Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Recherche Agronomique (INRA)

Subjects

010506 paleontology, Archeology, 10Be cosmic-ray exposure dating, 010504 meteorology & atmospheric sciences, 01 natural sciences, Allerød oscillation, Paleontology, Deglaciation, Younger Dryas, Glacial period, French Alps, Geomorphology, Ecology, Evolution, Behavior and Systematics, Holocene, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, Global and Planetary Change, geography, geography.geographical_feature_category, Geology, Glacier, Glacier fluctuations, [SHS.GEO]Humanities and Social Sciences/Geography, U-shaped valley, Late Glacial, 13. Climate action, Moraine

Abstract

Cosmic-ray exposure (CRE) dating of moraines allow glacier fluctuations and past climate change reconstructions. In the French Alps, there is a lack of moraine dating for the Late Glacial/Holocene transition period. Here we present a chronology of glacier advances in the Upper Romanche valley (French Alps – Massif des Ecrins) based on 10 Be CRE dating. CRE ages of moraines of 13.0 ± 1.1 ka and 12.4 ± 1.5 ka provide evidence for two stages of glacial advance or standstill at the end of the Late Glacial. The CRE dating of a rock avalanche deposit at 12.2 ± 1.5 ka is attributed to post-glacial debuttressing and reveals rapid deglaciation at the end of the Late Glacial. A CRE age of 7.1 ± 0.7 ka of a second mass-wasting, whose triggering factor is unidentified so far, indicates that up to an altitude of 2300 m a.s.l., the valley was ice-free as of ∼7 kyr at the latest. The re-evaluation of 21 moraine 10 Be CRE ages from nine glacial valleys across the Alps shows multiple glacial advances occurring at the Late Glacial/Holocene transition. These results lead to a re-evaluation of the importance of cooling events during the Allerod and the Younger Dryas in the Alps.

Published

2016

43. HEAVY MINERAL ANALYSIS OF GLACIAL TILL IN NORTHERN AND SOUTH-CENTRAL INDIANA TO RECONSTRUCT PATH OF GLACIAL ICE

Author

G. William Monaghan and Alexander D. Sodeman

Subjects

geography, Paleontology, U-shaped valley, geography.geographical_feature_category, Heavy mineral, Glacial landform, Till plain, Glacier, Post-glacial rebound, Glacial period, Ice sheet, Geomorphology, Geology

Published

2016

44. Mapping the Glacial-Geomorphological Landforms in East Liddar Valley, NW Himalaya Kashmir India

Author

Suhail A. Lone

Subjects

geography, geography.geographical_feature_category, Glacial landform, 0208 environmental biotechnology, Glacial striation, Glacier, 02 engineering and technology, 020801 environmental engineering, U-shaped valley, Moraine, Outwash plain, Physical geography, Fluvial landforms of streams, Glacial period, Geology

Abstract

The paper presents a glacial geomorphological map of landforms produced by different glaciers in East liddar during the past. The map has been created as the necessary precursor for an improved understanding of the glacial history of the region, and to strengthen a program of dating glacial limits in the region. The map was produced using Landsat TM, ASTER DEM, Google Earth™ imagery and field validation. The different landforms which were mapped include: lateral moraines, terminal moraines, proglacial lakes, palaeo-cirques, erratic boulders, outwash plains, whale backs, glacial grooves, rochee mountanee, drumlins, glacial striations, hanging valleys debris/talus cones, subglacial material. Glacial-Geomorphological features are very significant for palaeo-climatic reconstruction, showing variations, temporally and spatially. At the same time these landforms, which are also altered by processes prevailing during interglacial period, helps in geo-environment studies.

Published

2016

45. Extracting the Glacial - Geomorphological Landforms in West Liddar (NW) Himalayas Kashmir India

Author

Omar Paul, Suhail A. Lone, Altaf Lone, and Khalid Omar

Subjects

U-shaped valley, geography, geography.geographical_feature_category, Moraine, Glacial landform, Drumlin, Glacial striation, Outwash plain, Glacier, Physical geography, Glacial period, Geology

Abstract

The paper presents a glacial geomorphological map of landforms produced by different glaciers in west liddar during the past. The map has been created as the necessary precursor for an improved understanding of the glacial history of the region, and to strengthen a programme of dating glacial limits in the region. The map was produced using Landsat TM, ASTER DEM, Google Earth TM imagery and field validation. The different landforms which were mapped include: lateral moraines, terminal moraines, proglacial lakes, palaeo-cirques, erratic boulders, outwash plains, whale backs, glacial grooves, rochee mountanee, drumlins, glacial striations, hanging valleys debris/talus cones, subglacial material. Glacio-Geomorphological features are very significant for palaeo-climatic reconstruction, showing variations, temporally and spatially. At the same time these landforms, which are also altered by processes prevailing during interglacial period, helps in geo-environment studies.

Published

2016

46. Dartmoor's overlooked glacial legacy

Author

Ed Anderson, David J.A. Evans, Andreas Vieli, Stephan Harrison, University of Zurich, and Evans, David J A

Subjects

geography, geography.geographical_feature_category, Stratigraphy, Ice stream, 1904 Earth-Surface Processes, Ice field, Paleontology, Geology, Glacier, Glacier morphology, 1911 Paleontology, U-shaped valley, 10122 Institute of Geography, Moraine, Glacial period, 910 Geography & travel, 1913 Stratigraphy, Ice sheet, Geomorphology, 1907 Geology, Earth-Surface Processes

Abstract

Traditionally regarded as a relict permafrost and periglacial landscape that lay beyond the limits of Pleistocene glaciation, the granite uplands of northern Dartmoor in south-west England in fact contain geomorphological evidence for the former existence of a plateau ice cap, making the area the location of the southernmost independent glacier mass in the British Isles. In addition to weakly U-shaped valleys, the most prominent evidence comprises arcuate and linear bouldery ridges and hummocky valley floor drift, which are interpreted as latero-frontal moraines deposited by the outlet glacier lobes of a plateau ice cap. Inset sequences of these depositional landforms, in association with meltwater channels, demarcate the receding margins of the glacier lobes. A numerical model of ice cap development shows that a predominantly thin plateau icefield type glaciation is required in order to produce significant ice flow into surrounding valleys. The highest and most extensive plateau areas were occupied by ice for the longest cumulative period of time throughout the Pleistocene, thereby explaining: (1) the lack of tors in such areas as the product of ‘average’ glacial conditions preferentially removing tors or dampening their production rates, (2) the survival of high relief tors during glaciation if they occupied summits too narrow to develop thick and erosive glacier ice, and (3) the survival of subdued tors in areas glaciated less regularly during the Pleistocene.

Published

2012

47. Late Quaternary glaciations in Far NE Russia; combining moraines, topography and chronology to assess regional and global glaciation synchrony

Author

Iestyn D. Barr and Chris D. Clark

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, Geology, Last Glacial Maximum, Glacier, U-shaped valley, Moraine, Physical geography, Glacial period, Ice sheet, Quaternary, Geomorphology, Ecology, Evolution, Behavior and Systematics, Chronology

Abstract

During various periods of Late Quaternary glaciation, small ice-sheets, -caps, -fields and valley glaciers, occupied the mountains and uplands of Far NE Russia (including the Verkhoyansk, Suntar-Khayata, and Chersky Mountains; the Kolyma-Anyuy and Koryak Highlands; and much of the Kamchatka and Chukchi Peninsulas). Here, the margins of former glaciers across this region are constrained through the comprehensive mapping of moraines from remote sensing data (Landsat 7 ETM+ satellite images; ASTER Global Digital Elevation Model (GDEM2); and Viewfinder Panorama DEM data). A total of 8414 moraines are mapped, and this record is integrated with a series of published age-estimates (n = 25), considered to chronologically-constrain former ice-margin positions. Geomorphological and chronological data are compiled in a Geographic Information System (GIS) to produce 'best estimate' reconstructions of ice extent during the global Last Glacial Maximum (gLGM) and, to a lesser degree, during earlier phases of glaciation. The data reveal that much of Far NE Russia (∼1,092,427 km 2 ) preserves a glaciated landscape (i.e. is bounded by moraines), but there is no evidence of former ice masses having extended more than 270 km beyond mountain centres (suggesting that, during the Late Quaternary, the region has not been occupied by extensive ice sheets). During the gLGM, specifically, glaciers occupied ∼253,000 km 2 , and rarely extended more than 50 km in length. During earlier (pre-gLGM) periods, glaciers were more extensive, though the timing of former glaciation, and the maximum Quaternary extent, appears to have been asynchronous across the region, and out-of-phase with ice-extent maxima elsewhere in the Northern Hemisphere. This glacial history is partly explained through consideration of climatic-forcing (particularly moisture-availability, solar insolation and albedo), though topographic-controls upon the former extent and dynamics of glaciers are also considered, as are topographic-controls upon moraine deposition and preservation. Ultimately, our ability to understand the glacial and climatic history of this region is restricted when the geomorphological-record alone is considered, particularly as directly-dated glacial deposits are few, and topographic and climatic controls upon the moraine record are difficult to distinguish. © 2012 Elsevier Ltd.

Published

2012

48. Sedimentology of a debris-rich, perhumid valley glacier margin in the Rakaia Valley, South Island, New Zealand

Author

David J.A. Evans, James Shulmeister, Glenn D. Thackray, Olivia M. Hyatt, and Uwe Rieser

Subjects

geography, geography.geographical_feature_category, Tidewater glacier cycle, Paleontology, Glacier, Glacier morphology, U-shaped valley, Arts and Humanities (miscellaneous), Outwash plain, Earth and Planetary Sciences (miscellaneous), Deglaciation, Glacial period, Glacial lake, Geomorphology, Geology

Abstract

The sedimentology and stratigraphy of a multi-phase glaciation sequence dating to Marine Isotope Stage 6 in the Rakaia Valley, South Island, New Zealand, is presented. This outcrop presents an example of the depositional signature of an end member of temperate valley glaciation, where voluminous sediment supply in a tectonically active setting combines with high annual temperatures and low seasonality to generate significant year-round glacifluvial activity. Such glacial systems produce geological-climatic units that are dominated by thick sequences of aggradational gravels and proglacial lake sediments trapped behind outwash heads during deglaciation. At Bayfields Cliff, outwash sequences record an oscillating glacier margin marked by a sequence of glacier-fed, Gilbert-type deltas. The deltas are cut by numerous small-scale, syndepositional, normal faults indicating both loss of glacier support and melt-out of buried ice. A larger-scale thrust fault system reflects late-stage ice overrun. Braid plain gravels and chaotic disturbed glacial lake sediments are also recorded. A notable feature of these systems is the virtual absence of till in an environment with much other evidence for proximal ice. Cumulatively we regard these sediment-landform associations as diagnostic of debris-laden, perhumid, temperate valley glacier systems.

Published

2012

49. OSL ages revealing the glacier retreat in the Dangzi valley in the eastern Tibetan Plateau during the Last Glacial Maximum

Author

Xianjiao Ou, Biao Zhang, and Zhongping Lai

Subjects

Marine isotope stage, geography, Plateau, geography.geographical_feature_category, Stratigraphy, Geology, Glacier, Last Glacial Maximum, U-shaped valley, Moraine, Earth and Planetary Sciences (miscellaneous), Physical geography, Glacial period, Geomorphology, Terminal moraine

Abstract

Mountain glaciers are highly sensitive to temperature and precipitation fluctuations and, thus, the deposits of glacier growth and retreat constrain climatic variables. The Dangzi valley, located on the northern slope of Queer Shan Mountain, eastern Tibetan Plateau, is influenced by Indian monsoon and has preserved four integrated sets of moraines and associated glacial sediments. Numerical ages are scarce in this area, even though the moraines have been investigated for decades. In this study, dating of the glacial tills and glaciofluvial deposits was undertaken using quartz optically stimulated luminescence (OSL). We conclude that: (1) OSL ages show good agreement with geomorphological features. The samples should have been well-bleached before deposition, otherwise it is rather impossibly that all the ages in the former three sets are overestimated to a similar degree due to poor beaching as the spatial and temporal dynamics vary within glaciated valley. (2) Mountain glaciers have reached the maximum extent at about 25-22 ka in Dangzi valley during the Last Glacial Maximum (LGM). Then the glaciers retreated several times and formed the last terminal moraine at about 16.5 ka, which may indicate the termination of LGM on the eastern Tibetan Plateau. (3) The age of DZ307 (54.0 +/- 4.7 ka) demonstrates that the glacial advance also occurred at Marine Isotope Stage (MIS) 3, and that the glacial advance was larger in MIS 3 than in LGM, which is in agreement with previous results in the adjacent Yingpu valley. (4) The glacial evolution during the LGM in the study area was possibly controlled by the temperature changes, which could response to the summer solar insolation in northern hemisphere. (C) 2012 Elsevier B.V. All rights reserved. Mountain glaciers are highly sensitive to temperature and precipitation fluctuations and, thus, the deposits of glacier growth and retreat constrain climatic variables. The Dangzi valley, located on the northern slope of Queer Shan Mountain, eastern Tibetan Plateau, is influenced by Indian monsoon and has preserved four integrated sets of moraines and associated glacial sediments. Numerical ages are scarce in this area, even though the moraines have been investigated for decades. In this study, dating of the glacial tills and glaciofluvial deposits was undertaken using quartz optically stimulated luminescence (OSL). We conclude that: (1) OSL ages show good agreement with geomorphological features. The samples should have been well-bleached before deposition, otherwise it is rather impossibly that all the ages in the former three sets are overestimated to a similar degree due to poor beaching as the spatial and temporal dynamics vary within glaciated valley. (2) Mountain glaciers have reached the maximum extent at about 25-22 ka in Dangzi valley during the Last Glacial Maximum (LGM). Then the glaciers retreated several times and formed the last terminal moraine at about 16.5 ka, which may indicate the termination of LGM on the eastern Tibetan Plateau. (3) The age of DZ307 (54.0 +/- 4.7 ka) demonstrates that the glacial advance also occurred at Marine Isotope Stage (MIS) 3, and that the glacial advance was larger in MIS 3 than in LGM, which is in agreement with previous results in the adjacent Yingpu valley. (4) The glacial evolution during the LGM in the study area was possibly controlled by the temperature changes, which could response to the summer solar insolation in northern hemisphere. (C) 2012 Elsevier B.V. All rights reserved.

Published

2012

50. Quaternary glaciation of the Tashkurgan Valley, Southeast Pamir

Author

Kathyrn A. Hedrick, Jie Chen, Lewis A. Owen, Zhaode Yuan, Alexander C. Robinson, Jinfeng Liu, Marc W. Caffee, Daniel B. Imrecke, Lindsay M. Schoenbohm, and Wenqiao Li

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, Glacial landform, Rock glacier, Geology, Glacier, Last Glacial Maximum, Paleontology, Kansan glaciation, U-shaped valley, Moraine, Glacial period, Geomorphology, Ecology, Evolution, Behavior and Systematics

Abstract

The Quaternary glacial history of Tashkurgan valley, in the transition between the Pamir and Karakoram, in Xinjiang Province, China was examined using remote sensing, field mapping, geomorphic analysis of landforms and sediments, and 10Be terrestrial cosmogenic nuclide dating. Moraines were assigned to four glacial stages: 1) the Dabudaer glacial stage that dates to the penultimate glacial cycle and/or earlier, and may represent one or more glaciations; 2) the Tashkurgan glacial stage that dates to early last glacial, most likely Marine Oxygen Isotope Stage (MIS) 4; 3) the Hangdi glacial stage that dates to MIS 2, possibly early MIS 2; and 4) the Kuzigun glacial stage that dates to the MIS 2, possibly the global Last Glacial Maximum, and is younger than the Hangdi glacial stage. Younger moraines and rock glaciers are present at the heads of tributary valleys; but these were inaccessible because they are located close to politically sensitive borders with Pakistan, Afghanistan and Tajikistan. Glaciers during the Dabudaer glacial stage advanced into the central part of the Tashkurgan valley. During the Tashkurgan glacial stages, glaciers advanced several kilometers beyond the mouths of the tributary valleys into the Tashkurgan valley. Glaciers during the Hangdi and Kuzigun glacial stages advanced just beyond the mouths of the tributary valleys. Glaciation in this part of the Himalayan–Tibetan orogen is likely strongly controlled by northern hemisphere climate oscillations, although a monsoonal influence on glaciation cannot be ruled out entirely.

Published

2012