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Snow-accumulation variability from seasonal surface observations and firn-core stratigraphy, eastern Wilkes Land, Antarctica

Published online by Cambridge University Press:  20 January 2017

Ian D. Goodwin*
Affiliation:
Australian Antarctic Division, Kingston, Tasmania 7050, Australia
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Abstract

Annual accumulation records were derived from two firn cores drilled at GD03 (69° 00’S, 115° 30’E, 1835m) and GD15 (69° 00’S, 130° 48’E, 2155m), which are separated by 750 km along the 2000 m contour in eastern Wilkes Land. The accumulation records, spanning the period 1930–85, show that annual accumulation has increased by 25% from 1960 to 1985, resulting in the highest accumulation rates in the 55 year records. Annual accumulation layers were identified in the firn cores using a firn-stratigraphic model (based on the observed characteristics and variability of the seasonal snow-surface layer) together with seasonal oxygen-isotope ratios. The accumulation records support other evidence for a similar recent increase across Antarctica. The greater increase over the long-term mean for 1930–85 in eastern Wilkes Land was observed at GD15 which is located on a northeast aspect slope near Terre Adèlie. It is suggested that the increase is the result of changes in the general atmospheric circulation pattern which have produced a higher annual frequency of precipitation events.

Type
Research Article
Copyright
Copyright © International Glaciological Society 1991

Introduction

An objective of the International Antarctic Glaciological Project (IAGP) over the past decade has been to measure and define the surface mass input to the Wilkes Land region of East Antarctica. As part of the IAGP, a 4 year spatial accumulation record (1981–85) was obtained in eastern Wilkes Land from cane measurements made along a 750 km traverse route by the Australian National Antarctic Research Expeditions (ANARE). The route follows lat. 69° S between long. 112° and 131° E (Fig. 1.) and approximately follows the 2000 m contour in a moderate accumulation zone dominated by katabatic winds. The author (Reference GoodwinGoodwin, 1990) previously reported the spatial snow accumulation and surface micro-relief distributions for eastern Wilkes Land, together with the mesoscale processes controlling these distributions.

Fig. 1. Location map of eastern Wilkes Land showing the two firn-core sites at GD03 and GD15 together with the ANARE traverse route.

A shallow (30–40 m) firn-core stratigraphy study was carried out in 1985 to determine the temporal accumulation record over the last 50 years at two sites along the 2000 m contour in eastern Wilkes Land. The two sites were located at GD03 (69° 00’S, 115° 30’E, 1835m) and GDI5 (69° 00’S, 130° 48’E, 2155 m) (Fig. 1.). A study of surficial processes, snow-accumulation variability and seasonal firn stratigraphy was carried out at GD03 to estimate the variation in the horizontal extent and vertical thickness of the annual layer due to surface micro-relief or roughness. The results of this snow-surface study are presented here together with a firn stratigraphie model for eastern Wilkes Land. The model was applied to the two firn cores from GD03 and GD15. The resulting 55 year (1930–85) annual accumulation records are discussed with respect to temporal variability and are compared to other recent short-term accumulation records across Antarctica.

Seasonal Development of the Surface Snow Layer

A cane farm comprising 100 bamboo canes was established at GD03 to define snow-surface variability, the charcteristics of the seasonal snow layer and the regional firn stratigraphic model. Two arms of 50 canes spaced at 1 m intervals were set up to intersect at right-angles with one arm parallel to the prevailing katabatic surface-wind direction. The snow-surface topographic profile and the net snow accumulation at each cane were determined by cane measurements during autumn, spring and summer 1985. Surface micro-relief type, size and orientation measurements, together with surface density and hardness measurements, were also made. In order to extend the measured record to cover 2 years of accumulation, a total of 21 2 m deep snow cores were drilled at 5 m intervals along each of the arms. These cores were measured in detail for visible stratigraphy, density and seasonal oxygen-isotope δ18O values.

Three distinct, seasonal snow surfaces were observed to form in autumn, spring and summer. The characteristics of each of these surfaces are found in Table 1. The autumn wind-glazed ice crust forms over a wind crust during a major hiatus in snow supply and, consequently, marks the end of the balance year. Reference JonesJones (1983) attributed these ice crusts to surface melting which resulted from kinetic energy loss under strong katabatic wind flow. Beneath the wind crust is a layer of depth hoar which forms in snow deposited as surface hoar or from light snowfalls during mid-late summer (post-December). Light surface winds prevail during the summer and consequently redistribution processes are at a minimum, preserving the surface-hoar layer. Beneath the hoar layer is the summer surface which is characterized by a thin ice layer formed from the regelation of a surface-melt film caused by solar radiation during late spring to midsummer (November-December). This ice layer or radiation glaze is spatially discontinuous and its distribution is dependent upon the spring surface roughness. A wind-glazed crust also forms on the surface during late winter and/or spring when a hiatus in the snow supply occurs. However, the winter or spring glazes are not as well developed or as thick as the autumn glaze because precipitation is more frequent. The maximum development of the autumn glazed surface is correlated with the occurrence of the strongest surface winds in autumn (Reference AllisonAllison, 1985). Occasionally, depth-hoar layers occur in the upper 100–300 mm of snow dunes. The cane measurements and the oxygen-isotope values show that the majority of annual accumulation is derived from precipitation between early winter to late spring.

Table 1. Surface-layer characteristics

A standard model of firn stratigraphy was developed from the above observations and is similar to that used by Reference AlleyAlley (1988). The firn-stratigraphy model interprets the annual autumn wind-glazed ice crust overlying the summer hoar and radiation glazed surface as the annual horizon marker.

Spatial Variability of Snow-Accumulation Rates

A 2 year record of annual accumulation rate, seasonal micro-relief and snowpack development was determined for the summer 1984 to summer 1986 epoch at GD03 using sequential seasonal topographic profiles obtained from the survey measurements and short-core stratigraphy across the cane farm. The mean accumulation rate for the epoch 1984–86 was 390 kg m−2 a−1. The spatial variability (standard deviation/mean) of accumulation rate (due to surface micro-relief or roughness) for a single-year increment was 18%. The highest variability occurs during the autumn epoch when high sastrugi and barchan dunes dominate (Table 1).

Temporal Variability of Snow-Accumulation Rates

Using the PICO (Polar Ice Coring Office) lightweight auger, a 31 m long firn core was drilled adjacent to the cane farm at GD03. The GD03 core represents 55 years of annual snow-accumulation increments which were interpreted from the combined stratigraphie analyses of density, oxygen-isotope and visible layering. A vertical profile of density, δ18O and the position and thickness of annual autumn ice-crust layers is shown in Figure 2. The majority of autumn ice crusts (approximately 80%) can be matched to clear annual cycles in δ18O values despite the coarse sampling of δ18O at five samples per year. The annual snow-accumulation increments were converted to mass using the density profile (shown in Figure 2) to adjust for the compaction of firn layers with depth. The resulting accumulation record did not require any adjustment for the upstream accumulation gradient since this was negligible over the 2 km distance upstream, from which the snow originated. The mean annual accumulation rate for the period 1930–85 at GD03 was calculated as 315 kg m −2 a−1 with an inter-annual variability (standard deviation/mean) of 24%. This inter-annual variability has a larger magnitude than the single-year spatial accumulation variability of 18% measured across the cane farm because it includes additional variability due to temporal fluctuations in the precipitation regime.

Fig. 2. GD03 density, δl8O and ice-crust thickness profiles together with the interpreted annual autumn ice-crust layers.

A second annual accumulation-rate record was determined using the same methodology for a core at GD15 which is located 750km to the east of GD03 (Fig. 1) in a similar geographic setting. A vertical profile of density, δ18O and the position and thickness of annual autumn ice-crust layers is shown in Figure 3. The mean annual accumulation rate for the interval 1935–85 at GDI5 is 299kgm−2a−1 with an inter-annual variability of 22%. The annual accumulation-rate records for both cores were normalized against the long-term mean for the 1930–85 and 1935–85 epochs, respectively. They were also filtered using a seven-point Gaussian weighted running mean to minimize the effects of spatial variability. The resulting normalized accumulation records are shown in Figure 4. The two records display good correlation indicating that they do not contain residual variability due to local effects at the sites, but rather reflect the temporal variability due to regional climatic effects across Wilkes Land. The correlation also indicates that there are not systematic errors in the independent dating of the two cores. The accumulation records display an overall increase from 1930 to 1985 with a marked decrease between 1955 and 1965, centred around 1960. Since the early 1960s the accumulation rate has steadily increased to the mid 1980s, resulting in the highest accumulation rates in the 50 year period.

Fig. 3. GD15 density, δ18O and ice-crust thickness profiles together with the interpreted annual autumn ice-crust layers.

Fig. 4. Normalized and 7year Gaussian-filtered accumulation record for GD03 and GD15 sites between 1930 and 1985. The solid line represents the GD03 record and the dashed line represents the GD15 record.

For comparison with other short-term Antarctic accumulation records, this recent trend in increasing accumulation at both sites was analysed between two epochs, 1955–65 and 1975–85, together with a comparison with the long-term mean for 1930–85. The results are listed in Table 2. The results show that recent accumulation rates have increased by approximately 25% since 1960 across eastern Wilkes Land. This increase is comparable to the recent increases reported in other Antarctic regions. Reference Pourchet, Pinglot and LoriusPourchet and others (1983) reported a general increase of 30% (with a large variability from 10 to 90%) in accumulation for 14 sites in East Antarctica for the decade 1965–75 when compared to the previous decade 1955–65. These sites were mainly below 3000 m elevation in Terre Adèlie but also include: Vostok (78° 28’S, 106° 49’E), Dome C (74° 34’S, 123–10’E), South Pole and the Ross Ice Shelf. Reference Peel, Bradley and JonesPeel (in press) has reported a 20% increase in accumulation since 1955 from continuous records for three firn cores drilled on the Antarctic Peninsula. These studies confirm that the observed accumulation increase in Wilkes Land is a widespread phenomenon. However, the magnitude of the regional increases across Antarctica are variable and difficult to compare accurately because of differences in reference epochs.

Table 2. Accumulation-rate comparison

The autumn wind-glazed ice-crust thickness profile for GD03 shown in Figure 2 indicates a marked decrease in crust thickness since 1970 which is inversely correlated with the increase in accumulation. The greater ice-crust thicknesses observed prior to this period are not the result of temperature-gradient metamorphism as they maintain their layering integrity, which is identical to that observed for surface ice crusts. Consequently, the observed decrease in ice-crust thickness may indicate that the recent increase in annual accumulation is the result of shorter hiatus between precipitation events, especially during autumn.

Reference GoodwinGoodwin (1990) found that the GD15 region received a relatively high accumulation rate for its 2155 m elevation which was attributed to greater regional precipitation due to orographic and climatic effects. From the analysis of the long-term accumulation records in Table 2, both GD03 and GD15 have identical accumulation rates for the 1975–85 epoch despite the 327 m elevation difference. However, comparison of the accumulation records for the recent 1975–85 decade with those for the long-term mean (1930–85) indicates that the recent accumulation increase has been slightly (1.4 times) greater at GD15 than GD03. The relatively higher accumulation increase on the northeast aspect slope over the decade 1975–85 is most probably due to greater regional precipitation produced by an increase in cyclonic activity. Such an increase in cyclonic activity near GDI5 could result from an easterly shift or intensification in the quasi-stationary cyclonic position centred near 100° – 110° E, north of Casey Station, (Reference BromwichBromwich, 1988) in the circumpolar low-pressure trough. Analysis of mean monthly (June, July and August) pressure data for the circumpolar low-pressure trough over the period 1958–89 has shown that the quasi-stationary cyclone near Casey Station has intensified over this period (personal communication from R. Allen, CSIRO Division of Atmospheric Research). Reference BromwichBromwich (1988) found that the greatest precipitation occurred to the east of the vortex centre and that the amount of precipitation was governed by cyclonic intensity. Therefore, it is consistent to interpret the recent accumulation increase and its regionality across Wilkes Land as the result of an eastward intensification of cyclonic activity.

Conclusions

A continuous wind-glazed ice crust was observed to form on the snow surface in eastern Wilkes Land during major hiatus in snow supply during autumn. The wind-glazed ice crust was also observed as a preserved marker layer in the snowpack. This layer overlies a summer hoar layer and provided a reliable stratigraphie model together with oxygen-isotope (δ18O) values to interpret annual accumulation-rate records in firn cores from two sites in eastern Wilkes Land. A detailed study of the spatial variability of accumulaton rate across a cane farm at GD03 found that annual spatial variability accounts for approximately 75% of the observed inter-annual variability in the cores.

The accumulation-rate records from two sites (GD03 and GD15) span the period 1930–85 and show annual accumulation has increased by 25% from 1960 to 1985 which has resulted in the highest accumulation rates in the 55 year record. This accumulation increase across 750 km of eastern Wilkes Land supports evidence by Reference Pourchet, Pinglot and LoriusPourchet and others (1983) and Reference Peel, Bradley and JonesPeel (in press) for a similar increase across Antarctica. The increase in annual accumulation has been greatest at GDI5 (on the northeast aspect slope) where accumulation during the 1975–85 epoch is 21% higher than the long-term mean for 1930–85, compared to 15% for the same epochs at GD03 (on the northwest aspect slope). A probable explanation for the increase is a greater frequency of precipitation events due to changes in the general circumpolar atmospheric circulation pattern. The regionality of the increase in Wilkes Land may be controlled by an easterly intensification in cyclonic activity centred near 100° – 110° E (Reference BromwichBromwich, 1988) in the circumpolar low-pressure trough.

Acknowledgements

The field work was enthusiastically carried out by members of the 1985 ANARE eastern Wilkes Land glaciological traverses. The author also wishes to thank E. Wishart for assistance with the oxygen-isotope analyses and his colleagues V. Morgan and N. Young for discussion.

The accuracy of references in the text and in this list is the responsibility of the author, to whom queries should be addressed.

References

Alley, R. B. 1988. Concerning the deposition and diagenesis of strata in polar firn. F. Glaciol., 34(118), 283290.Google Scholar
Allison, I. 1985. Diurnal variability of the surface wind and air temperature at an inland Antarctic site: 2 years of AWS data. ANARE Res. Notes 28, 8192.Google Scholar
Bromwich, D.H. 1988. Snowfall in high southern latitudes. Rev. Geophys., 26(1), 149168.Google Scholar
Goodwin, I.D. 1990. Snow accumulation and surface topography in the katabatic zone of eastern Wilkes Land, Antarctica. Antarct. Sci., 2(3), 235242.Google Scholar
Jones, D.J. 1983. Snow stratigraphy observations in the katabatic wind region of eastern Wilkes Land, Antarctica. ANARE Res. Notes 17.Google Scholar
Peel, D. A. In press. Ice-core evidence from the Antarctic Peninsula region.In Bradley, R. S. and Jones, P. D.eds. Climate since 1500 A.D. London, Harper Collins Academic.Google Scholar
Pourchet, M., Pinglot, F. and Lorius, C. 1983. Some meteorological applications of radioactive fallout measurements in Antarctic snows. J. Geophys. Res., 88(C10), 60136020.Google Scholar
Figure 0

Fig. 1. Location map of eastern Wilkes Land showing the two firn-core sites at GD03 and GD15 together with the ANARE traverse route.

Figure 1

Table 1. Surface-layer characteristics

Figure 2

Fig. 2. GD03 density, δl8O and ice-crust thickness profiles together with the interpreted annual autumn ice-crust layers.

Figure 3

Fig. 3. GD15 density, δ18O and ice-crust thickness profiles together with the interpreted annual autumn ice-crust layers.

Figure 4

Fig. 4. Normalized and 7year Gaussian-filtered accumulation record for GD03 and GD15 sites between 1930 and 1985. The solid line represents the GD03 record and the dashed line represents the GD15 record.

Figure 5

Table 2. Accumulation-rate comparison