Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-23T16:02:39.068Z Has data issue: false hasContentIssue false

Complexity of the climatic regime over the Lambert Glacier basin of the East Antarctic ice sheet: firn-core evidences

Published online by Cambridge University Press:  08 September 2017

Xiao Cunde
Affiliation:
Laboratory of Ice Core and Cold Regions Environment Research Institute, Chinese Academy of Sciences, Lanzhou, Gansu 730000, China
Ren Jiawen
Affiliation:
Laboratory of Ice Core and Cold Regions Environment Research Institute, Chinese Academy of Sciences, Lanzhou, Gansu 730000, China
Qin Dahe
Affiliation:
Laboratory of Ice Core and Cold Regions Environment Research Institute, Chinese Academy of Sciences, Lanzhou, Gansu 730000, China
Li Zhongqin
Affiliation:
Laboratory of Ice Core and Cold Regions Environment Research Institute, Chinese Academy of Sciences, Lanzhou, Gansu 730000, China
Sun Weizhen
Affiliation:
Laboratory of Ice Core and Cold Regions Environment Research Institute, Chinese Academy of Sciences, Lanzhou, Gansu 730000, China
Ian Allison
Affiliation:
Antarctic CRC and Australia Antarctic Division, Box 252-80, Hobart, Tasmania 7001, Australia
Rights & Permissions [Opens in a new window]

Abstract

Type
Correspondence
Copyright
Copyright © International Glaciological Society 2001

Sir,

Deep ice-core records from Antarctica and Greenland indicate rather similar climate histories over long time-scales (Reference BenderBender and others, 1994; Reference JouzelJouzel, 1994; Reference Kreutz, Mayewski, Meeker, Twickler, Whitlow and PittalwalaKreutz and others, 1997), but over decadal to centennial scales the records from different regions of the Antarctic ice sheet show large differences. For instance, although increasing accumulation rates have been reported for many sites (Reference Pourchet, Pinglot and LoriusPourchet and others, 1983; Reference Peel and MulvaneyPeel and Mulvaney, 1988; Reference Morgan, Goodwin, Etheridge and WookeyMorgan and others, 1991; Reference Mosley-ThompsonMosley-Thompson and others, 1995), several sites show decreasing trends (Reference Graf, Reinwarth, Oerter, Dyurgerov and MillerGraf and others, 1990; Reference Kameda, Nakawo, Mae, Watanabe and NaruseKameda and others, 1990; Reference Bindschadler, Vornberger and ShabtaieBindschadler and others, 1993; Reference Isaksson and KarlénIsaksson and Karlén, 1994; Reference Jiawen, Dahe and AllisonRen and others, 1999). A similar situation is apparent in isotope temperature records (Reference Isaksson, Karlén, Gundestrup, Mayewski, Whitlow and TwicklerIsaksson and others, 1996; Reference Jiawen, Dahe and AllisonRen and others, 1999). Here, we discuss firn-core records of accumulation and isotopic trends since 1940 deduced from the top sections of four cores drilled on the west and east sides of the Lambert Glacier basin (LGB; Fig. 1).

Fig. 1. Location map of the firn cores (empty circles) drilled over the LGB. The solid line is the traverse route of the Chinese National Antarctic Research Expedition (CHIMARE), and the dashed line is the route of the Australian National Antarctic Research Expedition (ANARE).

During the 1992 joint Australian–Chinese over-snow traverse on the west side of the LGB, we drilled two firn cores, MGA (68°39′ S, 60°15′ E; 1830 m a.s.l.) and LGB16 (72°49′ S, 57°20′ E; 2689 m a.s.l.), 27 and 15 m long, respectively. These cores were dated stratigraphically using isotopic profiles, electrical conductivity measurements, stratigraphy and known accumulation rates. A series of firn cores were drilled adjacent to each of the two sites to check the precision of the dating (Reference Jiawen, Dahe and AllisonRen and others, 1999). Between 1996 and 1998, a second pair of firn cores were extracted, DT001 (71°51′ S, 77°55′ E; 2325 ma.s.l.) and DT085 (73°22′ S, 77°01′ E; 2577 m a.s.l.), 50 and 52 m long, respectively. δ 18O and chemical series (Cl, Na+ and NO3 ) were used to cross-date these with a precision believed to be ±2 years for the upper 20 m (Reference DaheQin and others, 2000). Only top sections of these latter two cores were used in order to match roughly the time period corresponding with that of the MGA and LGB16 cores. The four cores were all re-sampled every 3 cm in the laboratory.

The annual variations of accumulation and the seven-point smoothed δ 18O profiles for the four cores are shown in Figure 2. The most remarkable feature is that both the isotopic temperature and the accumulation rate on the east side of the LGB have increased since 1940, while on the west side they have not. The accumulation rates at MGA and LGB16 display decreasing trends, with the rates of change respectively −2.4 and −0.7 kg m−2 a−1, but with no obvious change in δ 18O.

Fig. 2. Variations of the seven-point smoothed δ18O and the annual accumulation rates at DT001, DT085, MGA and LGB16 during the period 1940–1990s. Instrumental surface air temperature at Davis and Mawson is also shown. The regression lines are all significant at p = 0.05 confidence level, with coefficient values for DT001, DT085, MGA and LGB16, respectively, of r = 0.28, 0.14, 0.11, 0.10 for δ18O trends, and r = 0.20, 0.36, 0.43 and 0.30 for accumulation rates.

We suggest that the reason for the differences between the two sides of the LGB is that on the east side large amounts of moisture are advected inland, but on the west side the trajectory of the air mass is not directly inland from the coast, which reduces the link between temperature and accumulation rate (Reference DaheQin and others, 2000). We note that there is a similar pattern of fluctuation of accumulation rates and δ 18O between DT001 and DT085, but not between MGA and LGB16. Again, different circulation patterns between the two sides of the catchment may be responsible, or alternatively there may be post-depositional modification of the records on the west side. We have noticed the different spatial distribution of accumulation rates between the two sides of the basin (Reference DaheQin and others, 2000), and previous studies pointing out this difference have attributed it to the “rain-shadow” effect of the prevailing upper-level winds (Reference AllisonAllison, 1979; Reference Higham, Craven, Ruddell and AllisonHigham and others, 1997).

The decadal changes of accumulation rates and δ 18O in the four cores are presented in Table 1. An obvious decrease of accumulation rate and δ 18O occurred during the 1960s in the two cores from the east side, which was not observed on the west side. Accumulation at DT001 and DT085 has clearly increased since 1970 (0–17%), whereas for MGA and LGB16 it has decreased rapidly (10–14%). An increase of δ 18O in the range 0–0.8‰ has occurred since 1970 at DT001 and DT085, while the fluctuations are much more complicated at MGA and LGB16.

Table 1. Comparison of decadal accumulation and δ 18O values in the firn cores at MGA, LGB16, DT001 and DT085; the rates of change in accumulation and δ 18O since 1940 are also listed

Instrumental records at Davis and Mawson meteorological stations display the same difference in air temperature between the east and west sides of the LGB. Mawson is one of the few stations showing a temperature decrease in the past half-century (Reference JonesJones, 1995). Reference Jacka and BuddJacka and Budd (1998), summarizing the temperature and sea-ice-extent changes in Antarctica and the Southern Ocean, found that the coastal regions of the two sides have converse trends of temperature and sea-ice extent. Our study therefore supports the earlier suggestion that cooling over the west side of the LGB may be affected by increased airflow from the cold interior (Reference Jones and WigleyJones and Wigley, 1988; Reference Jacka, Budd, Weller, Wilson and SeverinJacka and Budd, 1991).

The LGB system occupies almost 106 km2 and drains around one-eighth of the East Antarctic ice sheet (Reference Higham, Craven, Ruddell and AllisonHigham and others, 1997). This study shows that the drainage basin breaks the smooth topography of the East Antarctic ice sheet into two different climatic regimes, though the two sides (DT001 and DT085 vs MGA and LGB16) are only 500–700 km apart. We believe that the records from the east side reflect climatic variations related to the south Indian Ocean, whereas those from the west side are probably much more complicated and caution should be exercised when relating them to regional and global climate change.

Acknowledgements

This work is supported by the Ministry of Science and Technology of China (grant No. 98-927-01-05), the Chinese Academy of Sciences (grant No. K2CX2-303, K2951-A1-205) and the Chinese Natural Science Foundation (grant No. 49971021).

19 February 2001

References

Allison, I. 1979. The mass budget of the Lambert Glacier drainage basin, Antarctica. J. Glaciol., 22(87), 223235.Google Scholar
Bender, M. and 6 others. 1994. Climate correlations between Greenland and Antarctica during the past 100,000 years. Nature, 372(6507), 663666.Google Scholar
Bindschadler, R., Vornberger, P. L. and Shabtaie, S.. 1993. The detailed net mass balance of the ice plain on Ice Stream B, Antarctica: a geographic information system approach. J. Glaciol., 39(133), 471482.Google Scholar
Graf, W., Reinwarth, O., Oerter, H. and Dyurgerov, M.. 1990. Isotopic and stratigraphical interpretation of a16m firn core nearby Druzhnaya I. In Miller, H., ed. Filchner–Ronne-Ice-Shelf-Programme. Report No. 4 (1990). Bremerhaven, Alfred Wegener Institute for Polar and Marine Research, 4649.Google Scholar
Higham, M., Craven, M., Ruddell, A. and Allison, I.. 1997. Snow-accumulation distribution in the interior of the Lambert Glacier basin, Antarctica. Ann. Glaciol, 25, 412417.CrossRefGoogle Scholar
Isaksson, E. and Karlén, W.. 1994. Spatial and temporal patterns in snow accumulation, western Dronning Maud Land, Antarctica. J. Glaciol., 40(135), 399409.Google Scholar
Isaksson, E., Karlén, W., Gundestrup, N., Mayewski, P., Whitlow, S. and Twickler, M.. 1996. A century of accumulation and temperature changes in Dronning Maud Land, Antarctica. J. Geophys. Res., 101(D3), 70857094.CrossRefGoogle Scholar
Jacka, T. H. and Budd, W. F.. 1991. Detection of temperature and sea ice extent changes in the Antarctic and Southern Ocean. In Weller, G., Wilson, C. L. and Severin, B. A. B., eds. International Conferenceon the Role of the Polar Regions in Global Change: proceedings of a conference held June 11–15, 1990 at the University of Alaska Fairbanks. Vol. I. Fairbanks, AK, University of Alaska. Geophysical Institute/Center for Global Change and Arctic System Research, 6370.Google Scholar
Jacka, T. H. and Budd, W. F.. 1998. Detection of temperature and sea-ice-extent changes in the Antarctic and Southern Ocean, 1949–96. Ann. Glaciol., 27, 553559.Google Scholar
Jones, P. D. 1995. Recent variations in mean temperature and the diurnal temperature range in the Antarctic. Geophys. Res. Lett., 22(11), 13451348.CrossRefGoogle Scholar
Jones, P. D. and Wigley, T. M. L.. 1988. Antarctic gridded sea level pressure data: an analysis and reconstruction back to 1957. J. Climate, 1(12), 11991220.Google Scholar
Jouzel, J. 1994. Ice cores north and south. Nature, 372(6507), 612613.Google Scholar
Kameda, T., Nakawo, M., Mae, S., Watanabe, O. and Naruse, R.. 1990. Thinning of the ice sheet estimated from total gas content of ice cores in Mizuho Plateau, East Antarctica. Ann. Glaciol., 14, 131135.Google Scholar
Kreutz, K. J., Mayewski, P. A., Meeker, L. D., Twickler, M. S., Whitlow, S. I. and Pittalwala, I. I.. 1997. Bipolar changes in atmospheric circulation during the Little Ice Age. Science, 277(5330), 12941296.Google Scholar
Morgan, V. I., Goodwin, I. D., Etheridge, D. M. and Wookey, C. W.. 1991. Evidence from Antarctic ice cores for recent increases in snow accumulation. Nature, 354(6348), 5860.Google Scholar
Mosley-Thompson, E. and 6 others. 1995. Recent increase in South Pole snow accumulation. Ann. Glaciol., 21, 131138.CrossRefGoogle Scholar
Peel, D. A. and Mulvaney, R.. 1988. Air temperature and snow accumulation in the Antarctic Peninsula during the past 50 years. [Abstract.] Ann. Glaciol., 11, 207.Google Scholar
Pourchet, M., Pinglot, J. F. and Lorius, C.. 1983. Some meteorological applications of radioactive fallout measurements in Antarctic snows. J. Geophys. Res., 88(C10), 60136020.Google Scholar
Dahe, Qin and 8 others. 2000. Primary results of glaciological studies along an 1100 km transect from Zhongshan station to Dome A, East Antarctic ice sheet. Ann. Glaciol., 31, 198204.Google Scholar
Jiawen, Ren, Dahe, Qin and Allison, I.. 1999. Variations of snow accumulation and temperature over past decades in the Lambert Glacier basin, Antarctica. Ann. Glaciol., 29, 2932.Google Scholar
Figure 0

Fig. 1. Location map of the firn cores (empty circles) drilled over the LGB. The solid line is the traverse route of the Chinese National Antarctic Research Expedition (CHIMARE), and the dashed line is the route of the Australian National Antarctic Research Expedition (ANARE).

Figure 1

Fig. 2. Variations of the seven-point smoothed δ18O and the annual accumulation rates at DT001, DT085, MGA and LGB16 during the period 1940–1990s. Instrumental surface air temperature at Davis and Mawson is also shown. The regression lines are all significant at p = 0.05 confidence level, with coefficient values for DT001, DT085, MGA and LGB16, respectively, of r = 0.28, 0.14, 0.11, 0.10 for δ18O trends, and r = 0.20, 0.36, 0.43 and 0.30 for accumulation rates.

Figure 2

Table 1. Comparison of decadal accumulation and δ18O values in the firn cores at MGA, LGB16, DT001 and DT085; the rates of change in accumulation and δ18O since 1940 are also listed