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Glacial benches in south Victoria Land

Published online by Cambridge University Press:  30 January 2017

C. Bull ,
B. C. McKelvey  and
P. N. Webb
C. Bull
Affiliation:
Institute of Polar Studies, The Ohio State University, Columbus, Ohio, U.S.A.
B. C. McKelvey
Affiliation:
Department of Geology, University of New England, Armidale, N.S.W., Australia
P. N. Webb
Affiliation:
New Zealand Geological Survey, Lower Nutt, New Zealand
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Abstract

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Type
Correspondence
Information
Journal of Glaciology , Volume 5 , Issue 37 , 1964 , pp. 131 - 134
Copyright
Copyright © International Glaciological Society 1964

Sir,

In a recent letter Reference McGregorMcGregor (1963) questioned our interpretation of benches that occur at 1,200–1,500 m. (and at other elevations) on the sides of the Wright and Victoria Valleys (Reference BullBull and others, 1962). We have interpreted the “benches” as having been carved by glaciers broader, shallower and higher than those which later cut the deeper U-form of the present valleys. However, McGregor considers that the benches are solely structural in origin and have been formed by differential erosion at the sandstone-dolcrite, sandstone-basement or dolcrite-basement contacts.

We agree with McGregor that the resistant dolerites form flat benches and terraces and that the sills exercise control over the topography, so that often benches are structurally controlled (Reference McKelvey and WebbMcKelvey and Webb, 1959, p. 722).

However, in many places, benches are not structurally controlled. At the eastern side of Bull Pass a well-preserved bench (Reference BullBull and others, 1962, Fig. 5) lies below the dolerite-basement contact. In the western part of the Olympus Range (Reference BullBull and others, 1962, Fig. 6, extreme left) the bench is cut in basement rocks far below the base of an overlying dolerite sill. The surface of the Labyrinth (Reference BullBull and others, 1962, Fig. 3) does not coincide with a dolerite-basement or sandstone-basement contact.

Figure 1 illustrates the relation between the lithology and the benches in the south-east part of Wright Valley. On the south side of the valley (right of the photograph) one bench is carved entirely within the basement, where the structure is so complex that it can have afforded no control to the altitude or attitude of the bench. On the south side of Dais (centre of Figure 1) a bench at the same height is cut below the dolerite-basement contact. Other benches on Dais (left of Figure 1) are cut entirely within the dolerite sheet.

Fig. 1. Glacial benches in south victoria land

Other photographs of the area, already published, also show benches which are not structurally controlled (Reference Webb and McKelveyWebb and McKelvey, 1959, Figs. 5 and 11).

We realize that much caution must be used in interpreting such glacially carved benches as being remnants of the glacier floor at an earlier stage. Many authorities have so interpreted them, for example, Reference HobbsHobbs (1911), Reference MatthesMatthes (1930), Reference ThornburyThornbury (1954) and Reference CottonCotton (1958), but the problem is far from being settled. Matched pairs of benches occur on the sides of the Wright Valley and the elevation of some of them at least is unrelated to structure. The cross-section of the valley in the area of Dais shows a pronounced U-in-U form, the uppermost U being defined by the highest benches on the valley sides and by the top of Dais. We have considered it unlikely that the shoulders of these benches would remain so well preserved if the benches were cut by a glacier which simultaneously occupied the deeper-cut central part of the valley. Hence we have interpreted the benches as indicating levels at which broader glaciers stood for a considerable period.

Since we wrote the first draft of this letter, the Editors of the Journal of Glaciology have brought to our attention a further criticism by Reference GunnGunn (1963).

Gunn’s suggestion that the “first glaciation benches” coincide with the top of the Pencplain Sill is covered by our remarks above.

We do not agree that the material in the South Fork can be called “an almost stagnant glacier” and do not understand Gunn’s criteria for this interpretation. Amongst other considerations, the weathering and stability of this moraine are very much greater than those of the ice-cored moraines at the eastern end of the valley and elsewhere in the ice-free area.

The marked difference in the weathering of this moraine and of the older “third glaciation moraine” farther east justifies our distinction between the “third” and “fourth” glaciations as we have defined them. Gunn suggests that, following the severance of an ice mass in the South Fork from its supply area (the present Upper Wright Glacier) the front of the isolated ice has retreated from the “third glaciation” moraines to the position shown in Gunn’s Figure 1. The gradual ablation of a starved ice mass could not account for the sharp demarcation line between the older and newer moraines, nor for the lobate shape illustrated. Our interpretation, that the “third” and “fourth glaciation moraines” are associated with separate advances of tongues from the inland ice, is fully compatible with the present field evidence.

Since 1959 much work has been done in the ice-free valleys. At present the picture we have given as a result of our reconnaissance seems to remain substantially acceptable. However, the interpretation of some observations has already been changed (Reference NicholsNichols, 1961, Reference Nichols1962; Reference BullBull, 1962; Reference Calkin and CailleuxCalkin and Cailleux, 1962) and considerable modifications, especially in the Victoria Valley system, have resulted from the work of Parker Calkin, Institute of Polar Studies, The Ohio State University, which will be completed and published in the near future.

We are grateful to Parker Calkin and other members of the Institute of Polar Studies for discussions on the subject. This letter has been written while one of us (Colin Bull) is engaged on National Science Foundation Grant G–20473.

24 June 1963

References

Bull, C. 1962. Quaternary glaciations in southern Victoria Land, Antarctica. Journal of Glaciology, Vol. 4, No. 32, p. 24041. [Letter.]Google Scholar
Bull, C., and others. 1962. Quaternary glaciations in southern Victoria Land, Antarctica, by C. Bull B. C. McKelvey P. N. Webb., Journal of Glaciology, Vol. 4, No. 31, p. 6378.CrossRefGoogle Scholar
Calkin, P. Cailleux, A. 1962. A quantitative study of cavernous weathering (taffonis) and its application to glacial chronology in Victoria Valley, Antarctica. Zeitschrift für Geomorphologie, Neue Folge, Bd. 6, Ht. 3–4, p. 31724.Google Scholar
Cotton, C. A. 1958. Geomorphology. Seventh edition. Christchurch, Whitcombe and Tombs.Google Scholar
Gunn, B. M. 1963. Quaternary glaciations in Victoria Land. Journal of Glaciology, Vol. 4, No. 36, p. 82930. [Letter.]Google Scholar
Hobbs, W. H. 1911. Characteristics of existing glaciers. New York, Macmillan Co.Google Scholar
McGregor, V. R. 1963. Structural or glacial benches? Journal of Glaciology, Vol. 4, No. 34, p. 49495. [Letter.]CrossRefGoogle Scholar
McKelvey, B. C. Webb, P. N. 1959. Geological investigations in south Victoria Land, Antarctica. Part II.Geology of upper Taylor Glacier region. New Zealand journal of Geology and Geophysics, Vol. 2, No. 4, p. 71828.Google Scholar
Matthes, F. E. 1930. Geologic history of Yosemite Valley. U.S. Geological Survey. Professional Paper 160.Google Scholar
Nichols, R. L. 1961. Multiple glaciation in the Wright Valley, McMurdo Sound, Antarctica. Abstracts of symposivm papers, tenth Pacific Science Congress of the Pacific Science Association, Honolulu, 1961, p. 317.Google Scholar
Nichols, R. L. 1962. Geology of Lake Vanda, south Victoria Land, Antarctica. American Geophysical Union. Geophysical Monograph No. 7, p. 4752.Google Scholar
Thornbury, W. D. 1954. Principles of geomorphology. New York, John Wiley and Sons, Inc.; London, Chapman and Hall, Ltd.CrossRefGoogle Scholar
Webb, P. N. McKelvey, B. C. 1959. Geological investigations in south Victoria Land, Antarctica. Part 1. Geology of Victoria Dry Valley. New Zealand Journal of Geology and Geophysics, Vol. 2, No. 1, p. 12036.Google Scholar
Figure 0

Fig. 1. Glacial benches in south victoria land