Knowledge of the age of the moraines in any area is essential for a complete understanding of the glacial history and fier possible correlation of events with other areas. When evaluating the parameters used to judge the age of moraines in Antarctica it is important to keep in mind the differences between moist temperate areas and arid polar areas from the standpoint of climate and glacier regimen and frost action, stream erosion and other geologic processes.

The McMurdo Sound area, Victoria Land, is perhaps the largest glacier-free area in Antarctica and one of the best localities on the continent to study past fluctuations of the edge of the continental ice sheet and the fronts of local alpine glaciers. The author, assisted by Norman R. Rivard, studied the glacial chronology of the ice-free area west, south and east of McMurdo Sound from 1 December 1957 to 10 February 1958, under the auspices of the United States National Committee of the International Geophysical Year. A statement of the glacial history of this area has been published (Reference PéwéPéwé, 1958[a], Reference Péwé[b], Reference Péwé1960[a], Reference Péwé[b], Reference Péwé[c]).

Reference Harrington and SpedenHarrington and Speden (1960) recently published a photograph and note describing moraines near a lobe of Taylor Glacier on the west side of McMurdo Sound; they suggest that these moraines can possibly be correlated with moraines deposited during glacial advances in 1820, 1850 and 1890 in New Zealand and in the European Alps. The author believes that the end moraines described by Harrington and Speden in front of a lateral bulge of the upper Taylor GlacierFootnote * in Beacon ValleysFootnote † (Fig. 1) are not 50 or 100 yr. old but are perhaps thousands of years old and can be correlated with late Fryxell stage moraines elsewhere in the McMurdo Sound area (Reference PéwéPéwé, 1960 [a]). The moraines in Beacon Valley were not visited by the author but were mapped in 1958 by using aerial photographs and extrapolating from moraines visited on the other side and in front of Taylor Glacier in Taylor Dry Valley.

Fig. 1. Sketch map of McMurdo Sound, Victoria Land, Antarctica showing the extent of existing glaciers. Letter symbols on marp are: E. Mount Erebus; NAF. Williams Noval Air Facility; D. Davis Glacier. (Base modified after U.S. Nay Hydro-graphic Office Chart No. 6636 (Ross Sea) 3rd ed., 23 September 1957)

The author believes these events are not “recent”. In the adjoining ice-free valley north of Taylor Dry Valley, Reference ClarkClark (1960) repeatedly refers to the prolific very recent glaciations and conspicuous rapid recent wastage of the glaciers.

The author also was tempted to correlate “fresh-looking” moraines near glacier fronts, and even younger ice-cored moraines present on most glaciers adjacent to ice fronts, with the moraines from Recent advances in North America and New Zealand with which he was familiar. However, he now thinks that these “recent-looking” moraines throughout the ice-free area of McMurdo Sound, including those figured by Harrington and Speden (Reference Harrington and Speden1960, fig. 1) (Fig. 2) are considerably older.

(Photograph by U.S. Nary, 6 December 1956. Idengification No. 156, F–32, VX–6, USN 4/60)

Fig. 2. Vertical air photograph of the lower end of Beacon Valley and part of Taylor Glacier, McMurdo Sound area, Victoria Land, Antarctica. The valley floor is covered with a micro-relief pattern of sand-wedge polygons formed in end and ground moraines. End moraines extend transversely across the valley roughly parallel to the vertical ice front. The black bar on the right represents a distance of approximately 500 m.

The following is now suggested as evidence for the antiquity of the moraines figured by Reference Harrington and SpedenHarrington and Speden (1960, p. 652) and for similar moraines in the McMurdo Sound area.

It has long been held that the regimen of Antarctic glaciers is sluggish. The precipitation in the area, as well as the continent in general, is very slight Reference Flowers(Flowers, 1958), and ablation of glacial ice is low because of the cold climate. Péwé photographed the positions of many glacier fronts in the McMurdo Sound area in 1957 and 1958 and compared them with the respective positions of the fronts as photographed from exactly the same localities 46 yr. earlier by Reference TaylorTaylor (1922). A photo-comparative study of many glacier fronts throughout the area, and further comparison of other glacial fronts with old maps, indicates that there is hardly a perceptible change in the positions of the glacial fronts and in the thicknesses of the lower ends of these glaciers in half a century (Reference PéwéPéwé, 1958 [c]). One of the fronts so studied was the present terminus of Taylor Glacier (Reference TaylorTaylor, 1922, fig. 3), about 25 miles from the Beacon Valley bulge described by Reference Harrington and SpedenHarrington and Speden (1960). If all rephotographed glacier fronts in the McMurdo Sound area (including the terminus of Taylor Glacier) show no movement of their fronts and no appreciable thinning or thickening of their lower ends during the last 50 yr., it would seem unlikely that the front of the Iateral bulge of Taylor Glacier into Beacon Valley would have retreated 0.5–1.0 mile in the last 50 or 100 yr.

Fig. 3. Diagrammatic sketch of a sand-wedge near Lake Fryxell, lower Taylor Dry Valley, McMurdo Sound, Antarctica. (Reproduced by courtesy of the Editor, American journal of Science)

The almost complete absence of organic material which can be dated by the radiocarbon method seriously handicaps a quantitative approach to the age of moraines and glacier fronts in this area. A unique organic material that does shed some light on the problem is that of the mummified seal carcasses found in the glacier-free area many miles from the sea (Reference PéwéPéwé and others, 1959). It is believed that these seals crawled miles onto the land and died for lack of food. The cold, arid climate prevented decay and the carcasses have been slowly eroding away by wind action over a long period. Radiocarbon dating of carcasses (Table 1) indicates that the seal remains range in age from 600 to 2,000 yr. (Reference PéwéPéwé and others, 1959). These dates indicate that the ice has not been over the area where the seals lay for this interval of time.

Table I

Although these dated remains give a minimum date for the retreat of ice, these carcasses were found at least a mile from a glacier front. Old carcasses that occur near to ice fronts would better support the suggestion that the ice fronts have not retreated recently. To further support this suggestion, a part of a carcass of a small crabeater seal that was found on the ground about 100 ft. (30.5 m.) from the vertical face of the front of Davis Glacier in Davis Valley was submitted for testing. This carcass was at an elevation of 1,170 ft. (356.6 m.) above sea-level and appeared to be of an immature individual inasmuch as it was only 24 in. (0.61 m.) long. It was dried, wind polished, and “tough”. The skull and teeth were weathered and some of the bones of the flippers were beginning to be “weathered out”. The hair on the bottom of the carcass was well preserved. The age of a piece of the flipper of this mummified seal carcass was determined by radiocarbon dating to lie between 200 and 1,200 yr.Footnote * This indicates that the area immediately adjacent to the front of Davis Glacier has not been covered by the ice for about 200 to 500 yr. and the ice has not, therefore, retreated from this spot recently. This evidence supports the hypothesis that glacial fronts in the other valleys of this area have not retreated during the last 50 to 100 yr.

The evidence for the latest glacial advance in the McMurdo Sound area is the presence of widespread ice-cored moraines adjacent to the fronts of many glaciers. Such ice-cored moraines are thought to be only 100 or 200 yr. old in other parts of the world (Reference TaylorPéwé and others, unpublished); however, radiocarbon dates of algae from extinct ephemeral pondsFootnote * that formerly existed on the shifting topography of the ice-cored moraine of the Koettlitz Glacier indicate that the moraine is at least 2,500 to 6,000 yr. old (Reference PéwéPéwé, 1960 [a]). Undoubtedly, climatic conditions here are such as to preserve ice-cored moraines for an incredible length of time compared with temperate or subarctic latitudes. Such an age for ice-cored moraines adjacent to glacial fronts also suggests that it has been a considerable length of time since the glaciers have retreated an appreciable distance.

The main argument by Reference Blake and HollinBlake and Hollin (1960) against the young age of the moraines described by Harrington and Speden is that a polygonal micro-relief pattern on the ground is uniformally well developed over the entire valley floor in question (Fig. 2). Reference Harrington and SpedenHarrington and Speden (1961) have replied to this comment. The author wrote informally to Harrington in 1960 pointing out that the polygons suggested a much older age for moraines than mentioned by him and Reference Harrington and SpedenSpeden (1960).

It appears, from the reply by Reference Harrington and SpedenHarrington and Speden (1961), that there is not a clear understanding of the origin and development of the “polygons” present in the McMurdo Sound area. The present author studied the polygons intensively for one season and observed similar polygons in Alaska and Canada for several years (Reference PéwéPéwé, 1952, Reference Péwé and Hansen1957, Reference Péwéin press). In both polar areas the polygons are generally 10 to 20 m. in diameter.

Reference PéwéPéwé (1959, Reference Péwéin press) believes that the polygons in both Alaska and Antarctica are caused by the formation of seasonally recurring thermal contraction cracks in the perennially frozen ground—cracks which are produced by the great changes in temperature from summer to winter. The intense stresses generated by a drop in ground temperature Reference Lachenbruch(Lachenbruch, 1959) result in the formation of a polygonal network of contraction cracks. It has been shown by Reference LeffingwellLeffingwell (1915, Reference Leffiingwell1919) that hoar frost, ice crystals and melt water periodically fill or partly fill the cracks to produce a narrow vein of ground ice in the permafrost of the northern cold areas. This ice vein is not destroyed by the expansion of ground in the summer and provides a zone of weakness for repeated cracking and ice growth in subsequent winters. Eventually a polygonal network of massive foliated ice masses (wedges) exists in the ground.

Because of the extreme aridity in Antarctica, especially of the west side of McMurdo Sound, the periodic contraction cracks are filled with clean sand which filters down from above in summer. Repeated cracking and filling produces a wedge-shaped body of sand instead of ice as in the northern polar areas (Fig. 3). These wedge-shaped masses of sand have been termed sand-wedge polygons by Péwé (Reference Péwé1959, fig. 2). The polygonal pattern itself has also been referred to as tesselations by Reference TaylorTaylor (1922).

The ice wedge or sand-wedge polygons should not be confused with patterned ground formed by sorting processes and which are different from contraction polygons in size, rate of formation and cycle of development. Such confusion has long been apparent in geology and engineering. The size and configuration of the contractional polygon is dependent upon the nature of material, moisture content and direction of tensile stresses Reference Black(Black, 1952), as well as the rate and total amount of cooling Reference Lachenbruch(Lachenbruch, 1959).

Sand-wedge polygons could conceivably form during the first year after the ground was uncovered from glacial ice. The initial size and form would not change rapidly, if at all. Later, some polygons can split into smaller contractional polygons. Ordinarily, the cracks open at about the same place every winter and the overall shape and size is preserved for thousands of years.

With this understanding of the origin of the contraction crack polygon it is obvious that the main change with time is the filling of the crack with ice or sand depending upon the environment (Reference PéwéPéwé, 1959, p. 550). The wedge filling constantly grows wider and the sediment adjacent to the wedge is tilted upward more and more to form a raised edge on the surface around the polygon (Fig. 3). In Antarctica the raised edges do not rise more than 0.33–0.50 m. above the ground surface because slumping and wind erosion act to wear down the ridge.

Neither the height of the ridge nor the size of the polygon can be used reliably to indicate age of the polygons. The width of the sand-wedge is a reliable index if the sand supply is stable. Very young polygons may have a sand-wedge of only a few millimeters in thickness hut very old ones may have wedges 1 or 2 m. wide. Exposures of the wedge fillings are rare and therefore this index of age is of limited use.

Because of the lack of exposure of wedge fillings another method was used to determine relative age of polygons in the McMurdo Sound area. The wider the wedge filling the greater was the distance between the crests of the raised edges of the polygonal furrows (Fig. 3). Many measurements were taken of crest distances across the trenches of polygonal furrows in many types of sediment, on many different land forms, and in different ice-free valleys. On the most recent of small flood plains on the west side of McMurdo Sound “normal” sized polygons are formed. The distance from crest to crest across the polygonal trench is 6–12 cm. These small furrows are too small to accumulate snow during a light snow fall, and, therefore, to outline the polygons as commonly seen in the area (Fig. 2) (Reference PéwéPéwé, 1959, fig. 1). These polygons on the most recent flood plains appear the same as they did 50 yr. ago when photographed by Taylor. It is obvious that it takes more than 50 yr., and no doubt thousands of years to have the intersecting shallow furrows or trenches widen to 1 to 2 M. (when measured at the crest edges). Such widths are common on the moraines of the Fryxell and Taylor stages (Fig. 4). During the early summer such trenches are commonly filled with snow and the surface of the ground has the appearance of a large mosaic pavement.

(Photograph by T L. Péwé, 18 December Reference Péwé and Hansen1957)

Fig. 4. Transverse section across the raised edges of sand-wedge polygons in glacial drift near Lake Bonney, upper Taylor Dry Galley, Mc Murdo Sound, Antarctica. The excavation extends down to the top of the permafrost table. A seasonal contraction crack under a sand-filled trough is shown in the foreground. Lag gravel covers the ground surface.

The well-developed polygonal ground is excellently shown in the front of the lobe of Taylor Glacier described by Harrington and Speden (Reference Harrington and Speden1960, fig. 1) (Fig. 2). These polygons were not visited on the ground but from air photographs they look similar to polygons in the lower part of Taylor Dry Valley. It is here suggested that the polygons shown in Figure 2 alongside of the lobe of Taylor Glacier have furrows which are one or more meters across at the ridge crest and therefore are of considerable antiquity, hundreds if not thousands of years old. In fact, Reference McKelvey and WebbMcKelvey and Webb (1959) state that the polygons on this valley floor are bounded by peripheral troughs “as deep as 4 feet”.