Introduction
Lack of understanding of polar glacial processes and their glaciogenic products provided the impetus behind this study. Because of the inferred influence of Taylor Glacier in the past glacial history of Taylor Valley (Reference Denton, Denton, Armstrong, Stuiver and TurekianDenton and others, 1971; Reference Stuiver, Stuiver, Denton, Hughes, Fastook, Denton and HughesStuiver and others, 1981), the present glacier was used as a model for assessing the behaviour of outlet polar glaciers.
The understanding of sediment transport by glaciers requires a knowledge of the dynamics and thermal conditions of the ice itself. The dynamics of glacier ice are best expressed by the mass balance and the consequent glacier flow, whereas the thermal regime is controlled by the geothermal heat flux, the mean annual surface temperature, ice velocity, and ice thickness. These glaciological conditions are basic to the understanding of the processes involved in producing, moving, and releasing glacial sediment in the Taylor Glacier system (Reference RobinsonRobinson, 1982, unpublished). This paper presents glaciological data collected from Taylor Glacier between 1975 and 1978, and applies the data to assess the present dynamic and thermal regime particularly at the base of the glacier.
A large ice dome, inland of Taylor Glacier, acts as a centre of outflow. Localized flow off the eastern slopes of the dome drains into Skelton, Ferrar, MacKay, and Taylor Glaciers, with very restricted flow to Wright Upper and Victoria Upper Glaciers (Reference Drewry and CraddockDrewry, 1982). Taylor Glacier is almost 100 km long from ice divide to snout (Fig. 1a). The accumulation area lies west of the Transantarctic Mountains, covering over 650 km2 with a maximum elevation of 2450 m. The ice divide is over 30 km west of the mountains and extends south-westward from Wright Upper Glacier in the north, then south-eastward to the Lashley Mountains in the south. In the lower glacier, the ablation area covers approximately 760 km2 and is over 60 km long.
Fig. 1. a. Map of Taylor Glacier, from the ice divide to the snout b. Map of Taylor Glacier depicting the area of averaged ablation and accumulation rates (in m water gear−1). Transverse lines A to G indicate the approximate position of ablation and velocity-pole lines. EL is the equilibrium line. Ice-surface contours are at 200 m intervals.
Ice Dynamics
Mass balance
Mass-balance investigations require that a glacier be divided into two areas, one characterized by net accumulation and the other by net ablation. Locating the zone of separation of these areas is rather difficult. Normally, at the end of the summer, a temperate glacier (as defined by Reference AhlmannAhlmann (1935)) can be readily seen as two distinct areas, one snow-covered (where the winter accumulation has exceeded the summer ablation), and the other, exposed glacier ice (where the reverse is true). The line of separation is termed the equilibrium line (EL). In polar regions, particularly in arid areas, the EL coincides with the boundary between dry snow and ice on the glacier surface (Reference MüllerMüller, 1962; Fig. 3). Surface ice loss in polar glaciers, in both accumulation and ablation areas, is almost entirely by sublimation. The little melt that does occur is significant only in the lower part of the ablation area for 1–2 months in the summer. The approximate position of the EL for Taylor Glacier was determined from air photographs flown between 1957 and 1973.
Fig. 3. Ice-surface movement for the ablation area of Taylor Glacier (lines C to G), measured between December 1975 and January 1978, and expressed as vectors of ice motion in a horizontal direction (in metres).
Measurement of accumulation. Accumulation along the route of the 1959–60 Victoria Land traverse was derived from 19 snow pits (Reference Stuart and HeineStuart and Heine, 1961) and averaged 0.16 m water year−1 for the area inland from McMurdo Sound. The Taylor Glacier accumulation area is, on average, 200–300 m lower in elevation than the inland stations occupied by Reference Stuart and HeineStuart and Heine (1961); thus, a good approximation of net accumulation is 0.13 ± 0.02 m water year−1, or 0.03 m waterFootnote * less than the averaged accumulation obtained from the Reference Stuart and HeineStuart and Heine (1961) inland snow pits.
Measurement of ablation. Ablation occurs by surface melting, sublimation, and cliff ablation and calving. Surface ablation was measured at 62 pole sites and extrapolated to cover the entire ablation area of Taylor Glacier. The poles were placed in seven lines transverse to the glacier flow (Fig. 1b).
The close spacing of lines across the snout (A-C) was considered critical because of high ice-surface relief. Close spacing of the poles towards the margin enabled refined measurement of ablation, which was assumed variable due to the effects of snow drifting, shading, and high melt run-off.
The rate of ice ablation was obtained from the difference between the height of a pole measured on two separate occasions. The difference for measurements at the beginning and end of the measurement year (in metres) was converted to water-equivalent (m water) balance. Monitoring ablation for Taylor Glacier covered the period December 1975 to October 1978. The most complete ablation record for any one year was obtained during 1976 and 1977 (Table I). The other measurements, although incomplete, indicate similar ablation rates for the 3-year monitoring period. A mass balance was computed for the 1976–77 measurement year.
Table I. Measured Ice-Surface Lowering by Ablation (m Water year−1 ) on Taylor Glacier at Lines a to g for the Measurement Year, November 1976 —November 1977. The Estimated Error on Ablation Measurement is 7%
An estimate of mass balance. The loss of ice from Taylor Glacier by surface ablation was calculated by assuming that ablation rate is a linear function of elevation. The average ablation across lines A to G for the 1976–77 year was calculated, and a linear regression of ablation against elevation obtained (r = −0.87). The regression equation was then used to estimate the total ablation down-glacier of the equilibrium line. For the calculation, the ablation area was subdivided using the 200 m contours on the U.S.G.S. 1:250000 Taylor Glacier Sheet (ST 57–60/5). The area between the contours was planimetered and multiplied by the average ablation determined at the elevation midpoint on the regression line (Fig. 2). The derived volumes were then summed and converted to a mass loss for the ablation area for the measurement year. The total accumulation expressed as a mass gain was obtained by multiplying the estimated average accumulation (0.13 m water year−1) by the area of accumulation as defined by the ice divide (from Reference Drewry and CraddockDrewry, 1982) and the EL. Summing the mass loss and mass gain gives a mass balance (Table II) for the glacier measurement year.
Fig. 2. Ablation, in metres of water equivalent (m water), plotted against elevation (m a.s.l.), with a regression line (solid) through the plots of average measured ablation for lines C to G (•), and fixed at the equilibrium line. The area-averaged ablation is determined from the regression line. 0.13 m water is an estimate of the average accumulation for the entire accumulation area (accumulation is negative ablation).
Table II. Net Mass Balance for Taylor Glacier for the Measurement Year, November 1976 —November 1977. Error Limits for Mass Gain are ± 20% and for Mass Loss Are ± 7%
The estimated accumulation for the Taylor Glacier accumulation area is 84.9 × 106 tonnes for the measurement year 1976–77. However, additional ice input comes from Ferrar Glacier. Ice discharge through the cross-section beneath line F is calculated at 3.5 × 106 tonnes year −1, and the estimated discharge through Windy Gully is 0.6 × 106 tonnes year−1 Footnote * . Thus, the estimated ice gain for Taylor Glacier for the measurement year is 89.0 × 106 tonnes.
The estimated ice loss from the Taylor Glacier ablation area for the same measurement year is 79.5 × 106 tonnes and includes an estimate of 2.8 × 106 tonnes from ice-cliff ablation and calving. The ice-cliff ablation rate is an average of the ice-surface ablation between lines A and G (0.25 m water year−1), and represents an annual mass loss of 0.5 × 106 tonnes for the entire cliffed margin of Taylor Glacier. The ice-cliff calving was determined from the size and extent of the ice-margin avalanche apron at the beginning of summer (after Reference Bull and CarneinBull and Carnein, 1970). The avalanche apron, averaging 2 m thick and extending 9 m from the ice cliff, skirts almost 140 km of the glacier margin, and represents an annual mass loss of 2.3 × 106 tonnes from the ablation area.
The errors involved in balancing glacier mass are large and are attributable to definite sources: (1) defining the positions of the ice divide and equilibrium line; (2) determining glacier surface areas; (3) calculating ice-surface and ice-cliff ablation; and (4) estimating local accumulation from regional averages. These errors are random and are assessed by calculation and estimate, and expressed as a percentage. For Taylor Glacier the mass gain has a 19.7% errorFootnote * and the mass loss a 7.2% error.Footnote † Thus, the net mass gain of 9.5 × 106 tonnes computed for the year 1976–77 is 10.7% of the mass gain and within the calculated error.
Because of the large variability in mass balance, it is not possible accurately to deduce the equilibrium condition of Taylor Glacier. However, no visible change in the position of the Taylor Glacier terminal face was observed during this study, or between the years 1913 and 1960 (Reference Péwé and ChurchPēwē and Church, 1962). For the purpose of this study, Taylor Glacier is considered to be in balance, within the stated limits of error.
Glacier flow
Surface velocity. Taylor Glacier does not appear to have a simple flow pattern. Nevertheless, a reasonable approximation of the pattern was obtained from the surveyed lines (A to G). Horizontal velocity was measured, while the vertical component of velocity was assumed equal to the measured ablation rate.
Horizontal velocity measured between December 1975 and January 1978 is illustrated in Figure 3 and summarized in Table III. In each line, the velocity changes little across the central part of the glacier but decreases rapidly towards the sides. This is attributed to ice drag against the valley sides and decrease in ice thickness away from the glacier centre line, thus altering the thermal condition of the basal ice. The variation in ice velocity across the glacier is enhanced where the width is only four or five times the centre-line ice thickness (e.g. lines E and G). However, the across-glacier velocity profiles for lines A to D and F are less variable, probably due to wide ice cross-sections beneath these lines.
Table III. Magnitude of Surface-Ice Movement (m year−1) for Taylor Glacier during the Measurement Year, November 1976 —November 1977. Estimated Surveying Error Limits are ± 0.1 m for Lines A, B, C, F, and G, and ± 0.2 m for Lines D and E
Flow rates measured at line F are related to ice influx from Ferrar Glacier. The majority of the Ferrar Glacier ice flows to the north-east, down-valley. However, a small amount moves north-west into Taylor Glacier. The low surface velocities measured at line F probably result from compressional flow between Ferrar and Taylor Glaciers, as the former flows into the latter. Generally, however, measured surface velocities for Taylor Glacier exhibit ice under extensional flow. Such patterns of ice-surface velocity enable theoretical approximations of the englacial and basal components of ice flow.
Englacial and basal velocity. If the basal ice of a glacier is at pressure melting, a part of the measured surface velocity is likely to result from ice slip over the bed. To obtain the amount of basal slip, assuming temperate ice conditions at the glacier sole, an estimate of the englacial velocity is required. This allows basal velocity to be estimated as the difference between the surface velocity and englacial velocity.
In the absence of field measurements, horizontal englacial velocities for Taylor Glacier were theoretically determined using
which is derived from the generalized flow law of ice (Reference NyeNye, 1951), where β and n are constants.
Before reliable englacial velocities can be determined from Equation (1), specific values of β, which is dependent on temperature, are required. Ice temperatures in Taylor Glacier probably differ by 15 to 25 deg between the glacier surface and the sole. Under such conditions, the value of β is a function of position and could vary by nearly two orders over such temperature ranges (Reference GlenGlen, 1955). Since the flow law involves many simplifying assumptions and because of the uncertainty of the value of parameter β, the velocity profiles derived from Equation (1) are approximations.
Figure 4 presents the calculated englacial and basal velocities beneath the centre poles of lines C to G. The basal slip is large relative to the internal flow; presumably, this is the result of low basal shear stresses which result from high hydrostatic pressures. In areas where wet-base conditions are inferred to occur, the theoretically derived englacial velocity represents, on average, about 40% of the measured horizontal velocity at the ice surface. The remainder is taken up in basal slip and, therefore, is the main process contributing to horizontal ice movement in these areas of Taylor Glacier.
Fig. 4. Theoretically derived englacial horizontal velocity profiles for centre-line poles in lines C to G. Horizontal velocity is expressed in m year−1; ice thickness in metres.
Thermal Regime
Temperature modelling
The behaviour of most glaciers is critically dependent on temperature. The temperature distribution through a glacier is mainly determined by geothermal heat flow, mean annual surface temperature, ice thickness, the vertical component of ice velocity, and the heat generated by basal sliding and ice deformation.
When temperature modelling, it is normally assumed that the glacier is close to dynamic equilibrium; this has not been conclusively proved but is assumed for Taylor Glacier. The above features are reviewed and values for Taylor Glacier are found.
Geothermal heat flow. An estimate of the geothermal heat entering the base of Taylor Glacier was obtained from existing measurements in the region. Reference Decker and BucherDecker and Bucher (1977) presented data on sub-surface temperatures, thermal conductivities, and heat-flow values from permafrost sediment and bedrock. Preliminary calculations indicated a heat flow of 0.088 J m−2 s−1 for Dry Valley Drilling Project (DVDP) hole 6, drilled in granite at Lake Vida. This is more than twice the heat flow measured in other continental crustal terrains (e.g. Canadian shield with a heat flow of 0.038 J m−2 s−1 (Reference Clark and ClarkClark, 1966)).
The plutonic terrain beneath Taylor Glacier is similar to that around Lake Vida and therefore it seems reasonable to assume the same heat-flow value, particularly since Reference DeckerDecker (1978) explained the high heat flux by a convective model on a regional scale.
Mean annual surface temperature. It is commonly accepted that the temperature measured between 15 and 20 m beneath the glacier surface is a good approximation of the mean annual air temperature (MAAT) (Reference PatersonPaterson, 1981, p. 188). Calculation for Taylor Glacier showed that seasonal temperature changes are not detectable below a depth of 20 m (Robinson, unpublished) and that, at 17 m, the amplitude of change is unlikely to exceed 0.1 deg (Keys, unpublished). Therefore, the MAAT can be approximated by a measure of the mean annual surface temperature (MAST) at 17 m depth.
Measuring the MAST over the entire glacier is impractical. However, as a first approximation, it is assumed that the MAST decreases in a more or less linear fashion with increasing elevation (Reference HookeHooke, 1977), and the rate of decrease is termed the lapse-rate. In association with a measured MAST at a known elevation, the lapse-rate can be used to infer an approximate surface-ice temperature for different parts of a glacier or ice sheet.
A number of lapse-rates have been recorded for Antarctica. Reference Budd, Budd, Jenssen and RadokBudd and others (1971) obtained a lapserate of approximately 1.0 deg (100 m)−1 inland of the Wilkes Coast, and Reference TaylorTaylor (1965) computed a lapse-rate of 0.8 deg (100 m)−1 on a traverse to the South Pole. Reference Bentley, Bentley, Cameron, Bull, Kojima and GowBentley and others (1964) calculated a much lower lapse-rate at 0.35 deg (100 m)−1 for traverses that covered large areas but small ranges in elevation in West Antarctica.
Lapse-rates in the Dry Valleys area lie between the extremes quoted above. Calculations from the temperature and elevation measurements for Meserve Glacier (Reference HughesHughes, 1971; Reference HoldsworthHoldsworth, 1974) give a lapserate of 0.6 deg (100 m)−1. From surface ice-temperature measurements at different elevations on Taylor Glacier (Robinson, unpublished) a lapse-rate of 0.4 ± 0.05 deg (100 m)−1 was obtained. The latter is consistent with lapse-rates calculated by Keys (unpublished) from meteorological observations for the McMurdo Sound region.
At the snout of Taylor Glacier, the best fit between measured and calculated crevasse temperatures gives a MAST of −17.0°C at 17 m beneath the ice surface, whereas at lines F and G the 17 m temperatures are −20.1°C and −21.5°C, respectively. These ice temperatures are measured at known elevations, hence MAST values for any known elevation on Taylor Glacier can be estimated by extrapolation and interpolation using the calculated lapse-rate.
Ice thickness. Ice thickness for Taylor Glacier was obtained from gravity (Reference SternStern, 1978) and radio echosounding (Reference CalkinCalkin, 1974; Reference Drewry and CraddockDrewry, 1982) surveys, and is presented as simplified transverse profiles (Fig. 5). Both Reference CalkinCalkin (1974) and Reference Drewry and CraddockDrewry (1982) wrote of the subice terrain as bedrock. However, Reference SternStern (1978) found that the combined gravity and radio echo-sounding data for lines F and G were inconsistent with any simple two-layer model. The data required a third layer of density between that of ice and bedrock. The most reasonable value was the density of unconsolidated sediment (2.2 Mg m−3 ). Stern used this value in a three-layer model and calculated the maximum thickness of subglacial sediment to be 613 m for line F, and 563 m for line G, with the maximum thickness of ice beneath these lines as 640 m and 1110 m, respectively.
Fig. 5. Profiles of ice cross-sections beneath lines C, D, E, F, and G, Taylor Glacier (adapted from Reference SternStern (1978)). Approximate sediment thickness is included in the profiles at lines F and G. The intersection of gravity and radio echo-sounding profiles is marked (•) on profiles F and G.
At lines C, D, and E, where there are no echo-sounding control data for the corresponding gravity profiles, Reference SternStern (1978) explained the gravity profiles entirely by changes in ice thickness and assumed no sub-ice sediment.
Vertical ice velocity. Ice Velocity can be resolved into two components, horizontal and vertical. Although horizontal velocities are almost without exception the larger, the temperature gradient produced by horizontal velocity is quite small. A far more important process of heat transfer through an ice mass results from the vertical component of velocity.
Vertical velocities for Taylor Glacier were obtained from ablation rates in the ablation area (see Table I). The maximum vertical velocity (0.56 m year−1) occurs 400 m from the snout. An up-glacier progressive decrease in vertical velocity is assumed from the decrease in the averaged ablation (line C, 0.47 m year−1 line D, 0.36 m year−1 ; line E, 0.22 m year−1 ; line F, 0.11 m year−1 ; and line G, 0.16 m year−1) and this velocity is assumed to decrease linearly with depth.
No assessment of the downward velocity component in the accumulation area was attempted, as the accumulation rate for Taylor Glacier (0.13 m water year−1 ) is only an approximation and any temperature profiling for this area, using a single value of vertical velocity, would be misleading.
Internal heat generation. Because horizontal velocity decreases with depth, there is a shear deformation in the horizontal direction. Calculation of this deformation for Taylor Glacier indicates that upwards of 60% of the shear occurs just above the bed (see Fig. 4). All the frictional heat resulting from the deformation is assumed to be released at the base of the glacier.
In the lower ablation area of Taylor Glacier (down-glacier of line E), theoretical calculations show that the frictional heat produced in the basal ice (Q b) contributes between 6 and 12% to the total heat generated (Table IV). This extra heat input is greatest at the centre and decreases towards the margin. For lines C, D, and E, the calculated maximum increase in basal ice temperature due to heat from basal ice deformation is 1.5 deg. Beneath lines F and G the addition of internally generated frictional heat to the geothermal heat input at the ice base is calculated to increase the total heat by approximately 24 and 19%, respectively (Table IV), which is likely to increase basal ice temperatures by a maximum of 4.5 deg.
Table IV. Calculations of Frictional Heat (Q b) and Total Heat Generated (Q g + Q b) in the Basal Ice of Taylor Glacier Beneath the Centre of Lines C TO G
(Q g of 0.0880 J m−2 s−1 is assumed for Taylor Glacier.)
Calculation of basal ice temperatures
A number of mathematical models were reviewed for calculating Taylor Glacier basal-ice temperatures (Reference RobinRobin, 1955; Budd and others, [1970], 1971; Reference Philberth and FedererPhilberth and Federer, 1971; Reference HookeHooke, 1976, Reference Hooke1977; Reference JonesJones, 1978). The models of Budd and others, Philberth and Federer, and Jones were developed from Reference RobinRobin (1955) for ice-temperature modelling in accumulation areas. As the implicit requirement is that the accumulation rate be positive, this generally restricts the direct application of these models to regions above the equilibrium line. However, Robin’s model is readily modified for use in ablation areas:
Modification of the Budd and others’ model for use in the ablation area was presented by Reference HookeHooke (1976). Comparisons were made between ice temperatures derived from Hooke’s modification and the modification of Robin’s model for this study. In both the Hooke and modified Robin models, the vertical velocity is assumed to decrease linearly with depth. However, Hooke’s model accounts for internal heat generation from shear deformation at the glacier base, and the horizontal temperature gradient throughout the ice mass.
In Taylor Glacier, the heat generated from shear deformation could increase the basal heat input by 6–24% when added to the geothermal heat flow (see Table IV). Such additional heat is likely to be substantially greater than any cooling effects produced by horizontal advection in ice. Since Hooke’s model accounts for both internal heat generation and horizontal cooling (or warming), and basal temperatures derived using this model are warmer than those derived from the modified Robin model, it is assumed that the heat produced by internal deformation exceeds that from horizontal cooling. The lower temperatures derived using the modified Robin model indicate only the minimum approximate extent of the melting zones beneath Taylor Glacier (Fig. 6). The study of basal ice temperatures in Taylor Glacier was carried out to determine the presence of temperate ice and melting zones at the glacier sole. Therefore, it is sufficient to use a simplified model (Reference RobinRobin, 1955) that broadly delineates basal-ice thermal zones. This model probably underestimates the basal-ice temperature in Taylor Glacier and thus the melting zones detected will be underestimated, while the model of Reference HookeHooke (1976) gives larger zones of basal-ice melting.
Fig. 6. Map of areas of theoretically derived basal temperatures at 0°C (hachured) for the lower ablation area, Taylor Glacier.
The greatest errors were assumed in assessing vertical velocities and basal heat gradients. Therefore, the sensitivity of the basal thermal regime to changing these input variables was assessed: (i) when vertical velocities equivalent to the ablation rate and zero were separately applied to Equation (2); and (ii) when the basal heat was reduced by neglecting the frictional heat produced. By separately reducing both vertical velocity and basal heat influx, the area of basal melting is effectively reduced. For example, if the vertical velocities were neglected (i.e. Ḃ = 0 in Equation (2)) but equilibrium in the temperature profiles was maintained, the heat flow through the basal ice beneath lines E, F, and G would require only 80, 79, and 49%, respectively, of the estimated total geothermal heat supplied to the glacier sole. Such a heat reduction would just maintain the basal ice at 0°C. Any further heat loss would result in freezing at the base.
The effect of reducing the geothermal heat influx while maintaining the vertical velocity was also considered. Under such circumstances, a 9 to 79% decrease in the geothermal heat flow beneath C to G, respectively, is required before basal-ice melting is prevented beneath all the lines (assuming the temperature equilibrium is maintained throughout the ice column).
Figure 6 illustrates that about 50% of the lower ablation area of Taylor Glacier may be at pressure melting and therefore can be expected to behave as temperate ice. The area is a minimum, for the reasons already outlined, and because the glacier probably passes over extensive salt deposits (Keys, unpublished), which have the effect of depressing the freezing-point of the basal ice and thereby extending basal melt. Further investigation may reveal similar large areas of basal melting beneath the upper ablation area and into the accumulation area, extending the zones of melting beyond the restricted distribution discussed here and beyond the sub-ice lakes described by Drewry (1982) for the ice sheet west of Taylor Glacier.
Summary
The temperature distribution in the basal ice for the ablation area of Taylor Glacier was obtained from the following data:
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1. Mass loss from surface ablation (measured average 100 kg H2O m−2 year−1)and ice-cliff ablation (estimated average 1000 kg H2O m−2 year−1) for the ablation area, and mass gain from accumulation (estimated average 130 kg H2O m−2 year−1) and ice input from Ferrar Glacier (estimated total 4.1 × 106 tonnes H2O year−1) indicates that Taylor Glacier is close to mass-equilibrium conditions.
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2. Horizontal surface-ice velocity measured for the Taylor Glacier ablation area averages 6.1 m year−1, with a maximum of 14.4 m year−1 (line G). The vertical surface-ice velocity, estimated from the measured rate of surface ablation, averages 0.24 m year−1, with a maximum of 0.56 in year−1 (in line C). In areas of inferred basal melting, theoretically determined englacial velocity profiles indicate that between 25 and 83% (and on average 60%) of the surface velocity is the result of basal slip.
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3. A regional geothermal heat flow of 0.088 J m−1 s−1 was used to approximate the heat flow into the base of Taylor Glacier.
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4. Mean annual surface temperatures at the snout and equilibrium line of Taylor Glacier are −17.0°C and 24.6°C, respectively. These data were obtained from crevasse temperatures and extrapolation of drill-hole temperatures. A temperature lapse-rate of 0.40 ± 0.05 deg (100 m)−1 was also determined.
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5. Ice thickness, obtained from gravity survey and radio echo-sounding data, is on average 400–500 m in the ablation area. However, in restricted subglacial depressions the ice thickness exceeds 1000 m.
Assuming steady-state conditions, the distribution of basal temperatures for Taylor Glacier, determined from the above data, indicates that as much as 50% of the basal ice in the lower ablation area may be melting.
Acknowledgements
This study formed part of a doctoral dissertation and the author acknowledges with thanks the supervision and support of Dr P.J. Barrett, Antarctic Research Centre, Victoria University of Wellington. Financial support for this study was provided by a university post-graduate scholarship from Victoria University of Wellington. Logistic and field support was provided by the Antarctic Research Centre, the New Zealand Antarctic Division (DSIR), and the United States National Science Foundation. Special thanks are due to Drs P.J. Barrett and G.S. Boulton for critically reviewing parts of the manuscript.
