An Elemental Analysis of the Glacial Deposits of the Vestfold Hills, AntarcticaEntry ID: ASAC_135
Abstract: Metadata record for data from ASAC Project 135
Taken from the abstracts of some of the referenced papers:
Vestfold Hills, Antarctica exhibits marked contrasts in the weathering surface and glacial sediments between its eastern and western parts. The boundary between these zones coincides with a regional chemical boundary termed the 'salt line'. The area west of the salt line is saturated with ... marine-derived halite and thenardite that are particularly aggressive agents of rock weathering. In contrast, the area east of the salt line exhibits significantly fewer deposits of these salts. Rock surfaces west of the salt line are characterised by well-developed weathering forms, while glacial polish and striae are largely absent. In contrast, rock surfaces to the east commonly retain glacial polish and striae. In places, differential weathering has caused thin basaltic dykes and felsic veins to stand above the surrounding gneiss. The rate of lowering of the gneiss and dykes to the west of the salt line has been estimated at 0.024 mm and 0.015 mm per year respectively. These measurements suggest that the weathering surface in parts of the Vestfold Hills may record more than 70ka of subaerial exposure.
Glacial sediments are much more abundant, coarser and better sorted northwest of the salt line than to the southeast. The abundant grus produced by physical weathering is coarser grained and better sorted that that produced by subglacial erosion. Such sediment lying on the land surface would be transported and redeposited during glacial advances. The change in nature of the sediments to either side of the salt line, together with the weathering forms found on clasts in the moraines, indicates that the weathering surface prior to the last glacial advance was similar to that of today and must also have developed during long periods of subaerial exposure.
Radiocarbon dating of marine, lacustrine or terrestrial biogenic deposits is the main technique used to determine when deglaciation of the oases of East Antarctica occurred. However, at many of the oases of East Antarctica, including the Schirmacher Oasis, Stillwell Hills, Amery Oasis, Larsemann Hills, Taylor Islands and Grearson Oasis, snow and ice presently forms extensive blankets that fills valleys and some lake basins, covers perennial lake ice and in places overwhelms local topography to form ice domes up to hundreds of square kilometres in area. Field observations from Larsemann Hills and Taylor Islands suggest that under these conditions, terrestrial and lacustrine biogenic sedimentation is neither widespread nor abundant. If similar conditions prevailed in and around the oases immediately following retreat of the ice sheet, then a lengthy hiatus might exist between deglaciation and the onset of widespread or abundant biogenic sedimentation. As a result, radiocarbon dating might be a clumsy tool with which to reconstruct deglaciation history, and independent dating methods that record emergence of the hilltops from the continental ice must be employed as well.
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Start Date: 1988-09-30Stop Date: 1995-03-31
Quality Values provided in temporal and spatial coverage are approximate only.
See the referenced publications for more information.
These data are old, and have not been thoroughly quality checked.
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Please follow instructions listed in the citation reference provided at http://data.aad.gov.au/aadc/metadata/citation.cfm?entry_id=ASAC_135 when using these data.
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Role: TECHNICAL CONTACT
Role: DIF AUTHOR
Phone: +61 2 4921 5082
Fax: +61 2 4921 5877
Email: ggeac at cc.newcastle.edu.au
Department of Geography CALLAGHAN UNIVERSITY OF NEWCASTLE
Province or State: New South Wales
Postal Code: 2308
Gore D.B. (1992), Ice-damming and fluvial erosion in the Vestfold Hills, East Antarctica, Antarctic Science, 4, 2, 227-234
Gore D.B. (1993), Changes in the ice boundary of the Vestfold Hills, East Antarctica, 1947 to 1990, Australian Geographical Studies, 31, 1, 49-61
Gore D.B., Colhoun E.A., Bell K. (1994), Derived constituents in the glacial sediments of the Vestfold Hills, East Antarctica., Quaternary Science Reviews, 13, 301-307
Colhoun E.A., Mabin M.C.G., Adamson D.A., Kirk R.M. (1992), Antarctic ice volume and contribution to sea-level fall at 20,000 yr BP from raised beaches., Nature, 358, 316-318
Gore D.B., Creagh D.C., Burgess J.S., Colhoun E.A., Spate A.P., Baird A.S. (1996), Composition, distribution and origin of surficial salts in the Vestfold Hills, East Antarctica., Antarctic Science, 8, 1, 73-84
Gore D.B., Pickard J., Baird A.S., Webb J.A. (1996), Glacial Crooked Lake, Vestfold Hills, East Antarctica., Polar Record, 32, 180, 19-24
Gore D.B. (1997), Last glaciation of Vestfold Hills: extension of the East Antarctic ice sheet or lateral expansion of Sorsdal Glacier?, Polar Record, 33, 184, 5-12
Gore D.B. (1997), Blanketing snow and ice: constraints on radiocarbon dating deglaciation in East Antarctic oases., Antarctic Science, 9, 3, 336-346
Gore D.B. and Pickard J. (1998), Proglacial hydrology and drainage, southeastern Vestfold Hills, East Antarctica., Proceedings of the Linnean Society of New South Wales, 119, 181-196
Gore D.B. and Colhoun E.A. (1997), Regional contrasts in weathering and glacial sediments suggests long term subaerial exposure of the Vestfold Hills, East Antarctica Ricci C.A., The Antarctic Region: geological evolution and processes, 835-839
Gore D.B., Nichols G.T., Lehmann C.E.R., Burgess J.S., Baird A.S. and Creagh D.C. (2000), An atlas of surficial salts of the Vestfold Hills, East Antarctica: composition, distribution and origin, ANARE Report, 143, 146
Wright A.P., White D., Gore D.B., Siegert M.J. (2008), Chapter 11: Antarctica at the Last Glacial Maximum, Deglaciation and the Holocene, Florindo F., Siegert M.J. Antarctic Climate Evolution. Developments in Earth and Environmental Science, 8, 531-570
Creation and Review Dates
DIF Creation Date: 2000-07-19
Last DIF Revision Date: 2012-05-31