NZ
A. I. Gow
Figure L South side of Hobbs Glacier, showing abundant lami-nated debris composed mainly of dust particles and sand.
Figure 2. Close-up of contorted debris patterns in Garwood Glacier.Scale: distance from side to side of photograph is 50 centimeters.
The existence of relatively dirt-free ice between zonestends to indicate that the deposition of dust and sandoccurred on a. periodic basis. Most of the debris wasprobably derived by wind from sources of exposedrock in the Royal Society Range. Some of the debrismay be volcanic ash.
Additionally, the Garwood, Blue, and Taylor Gla-ciers all contain thick sequences of sand and gravelintercalated with bubbly glacial ice. Though ob-viously distorted by englacial deformation, these de-posits still possess such characteristic features ofwater-laid deposits as size sorting, crossbedding, andlensing (fig. 2). Further, the deposits occur at levelswithin the ice that seem to preclude any possibilityof their having been incorporated at the glacier bed,either by "freezing on" or by shearing. It is tenta-tively concluded that this debris was originally de-posited on top of the glaciers (in their accumulationareas) by melt streams or by avalanching duringsome period of ablation much more intensive than
the present. This period of ablation could con-ceivably be correlated with the climatic optimumof several thousand years ago.
During December 1971 the two 10-kilometer-longlines of snow stakes at Byrd Station were remeasured,and further measurements of deformation were madein the drill hole at old Byrd Station. Nearly 10 yearsof snow stake observations have shown that the largesurface depressions around Byrd Station are accumu-lating 30 to 50 percent more snow than the exposedcrests. Snow accumulation within a 10-kilometerradius of Byrd over the past 10 years has varied from8.6 to 15.7 grams per square centimeter per year, witha mean value of 11.7 grams per square centimeterper year.
Only the top 170 meters of the 308-meter-deep holeat old Byrd is still accessible for measurement with thedownhole probe. This part of the hole had been de-forming very slowly, but the latest data, taken nearly14 years after the hole was drilled, clearly show thataccelerating closure has set in at the lower stresses.
This work was supported by National Science Foun-dation grant AG-258.
Ogive systems on polar alpine glaciers
MAURICE J . MCSAVENEY
Institute of Polar StudiesThe Ohio State University
The inapplicability of the annual ablation-plasticdeformation model of surface wave, or wave ogive,formation (Nye, 1958) to polar alpine glaciers whoseannual motion is small has led to the development oftwo alternative mechanisms: a differential ablation-longitudinal compression model (Hughes, 1971) and astress-induced buckling model (Holdsworth, 1969).The differential ablation-longitudinal compressionmodel acts preferentially on equator-facing polaralpine glaciers, while the buckling model has univer-sal application, acting on all glaciers above a criticalstress value.
The purpose of the project, "Surface buckling onMeserve Glacier and adjacent glaciers, Wright Valley,Antarctica," is to test various models of ogive forma-tion and to find out how wave ogives are formed andmodified under polar alpine conditions. To this pur-pose, closely spaced surface strain networks were erec-ted on the ogive train of Meserve Glacier, deep andshallow boreholes were placed within these networks,ice samples were taken for fabric studies, and arealvariation in ablation was studied. In addition, otherogive systems in the McMurdo Sound region were ob-served. Some of this work was initiated by Dr. GeraldHoldsworth in 1964. The deep holes and the first of
July-August 1972 101
the closely spaced strain networks were installed in1968-1969 under the leadership of Dr. T. Hughes.This season's work was carried out by Eileen andMaurice McSaveney between November 4, 1971, andFebruary 4, 1972.
Important findings from this season include thediscovery that the Meserve Glacier ogive train is nota single train of waves but a system of two interdigita-ting trains symmetrically disposed about the center-line. Well developed ogive trains were located onpolar-facing alpine glaciers in the valley of theFerrar Glacier and in Pearse Valley. Poorly developedogives of polar orientation were observed in Taylorand Wright Valleys. Strain variation over ogive sys-tems is large and consistent with the ogive pattern.The largest wave form on Meserve Glacier is now arecumbent fold, flattening under gravity. Detailedablation determinations over a section of the MeserveGlacier ogive system suggest that previous estimates ofmass balance for Meserve Glacier (Bull and Carnein,1970) overestimate the ablation term by a smallamount. This error was a function of the large spacingof ablation poles, which did not sample either the fullspectrum of glacier microtopography or the ablationprocesses on Meserve Glacier. The redistribution of
mass by melting of ice exposed to direct solar radiationat low angles of incidence on wave "fronts" and therefreezing of water at high angles of incident solarradiation on the flatter wave "troughs" is an im-portant process. It does not lead to significant ac-cumulation of superimposed ice but merely retardsablation.
This work is supported by National Science Founda-tion grant GV-28804.
References
Bull, C., and C. R. Carnein. 1970. The mass balance of acold glacier: Meserve Glacier, south Victoria land, Antarc-tica. International Symposium on Antarctic GlaciologicalExploration, Hanover, New Hampshire, 3-7 September1968. International Association of Scientific Hydrology.Publication, 86. p. 429-446.
Holdsworth, G. 1969. Structural glaciology of MeserveGlacier. Antarctic Journal of the U.S., IV(4): 126-128.
Hughes, T. 1971. Nonhomogeneous strain studies on antarc-tic glaciers. Antarctic Journal of the U.S., V1(4): 89-90.
Nye, J. F. 1958. A theory of wave formation in glaciers.Union Géodésique et Géo physique Internationale, Associa-tion Internationale d'Hydrologie Scientifique, Symposiumde Chamonix 16-24 Sept. 1958. Physique du mouvementde la glace. p. 139-154.
Ancient ice wedges inWright Valley, Antarctica
ol-
EILEEN R. MCSAVENEY and MAURICE J . MCSAVENEYInstitute of Polar Studies
The Ohio State University
Until now, completely exposed cross sections of icewedges had not been recorded in Wright Valley,Antarctica. During the 1971-1972 antarctic summerseason the authors observed three complete ice-wedgesections in a single 2-meter-high, 25-meter-long ex-posure in a freshly cut terrace wall along the southbank of Onyx River. The largest wedge (fig. 1) is 106centimeters deep and at its widest 23 centimeterswide. It is overlain by 90 centimeters of sand wedgefill 25 centimeters wide. All ice wedges have a centralor subcentral crack 2 to 3 millimeters wide, partiallyfilled by hoar crystals. The ice contains about 10 per-cent sand by volume. It could not be determined ifsand in the cracks was deposited after the recent ex-posure of the wedges. The ice wedges are in OnyxRiver alluvium, dominantly a stratified, very coarsesand with occasional pebbles, overlain by a surficialcoating of an alluvial fan originating from MeserveGlacier. The alluvium is ice-cemented from belowbelow
M. I. McSaveney
Figure 1. Ice wedge beneath fine-sand wedge.
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