东南极昆仑站周边沿“中国墙”的冰厚和冰下地形分布

摘要
参考文献
相关文章

全文: PDF (921 KB) HTML ( KB) 输出: BibTeX | EndNote (RIS) 背景资料

摘要冰厚和冰下地形是南极冰盖的基本特征参数，是南极冰盖底部环境和物质平衡研究的基础。2007/08年，中国第24次南极科学考察期间，运用深部探测冰雷达系统，在东南极位于Dome A区域的我国南极昆仑站周边，开展了沿“中国墙”的冰厚和冰下地形探测。结果显示：沿“中国墙”的冰厚主要分布在1600m－2800m之间，冰厚最大达到3444m，最小为1255m；冰下地形平均高程为1722m，但是最低仅有604 m; 相较于分冰岭北侧，分冰岭南侧冰厚较大，冰下地形较低，并且发育了4个明显的冰下深谷。不过，没有发现Gamburtsev冰下山脉区域典型的冰底再冻结现象以及冰下湖和水体的存在。Bedmap 2中沿“中国墙”的冰厚和冰下地形数据与冰雷达测量结果存在一致性，但是分辨率和在冰下地形起伏剧烈区域的准确性上非常有限。通过冰雷达探测得到的沿“中国墙”的冰厚和冰下地形分布，进一步揭示了这一“不可接近区域”的冰盖特征，对于Dome A区域冰盖动力学研究和未来针对Gamburtsev冰下山脉的地质钻探以及深冰芯钻探选址具有重要参考价值。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	崔祥斌
	孙波
	苏小岗
	郭井学

关键词：南极冰盖昆仑站冰厚冰下地形冰雷达

Abstract： As fundamental parameters of the Antarctic Ice Sheet, ice thickness and subglacial topography are critical factors for studying the basal conditions and mass balance in Antarctica. During CHINARE 24 (the 24th Chinese National Antarctic Research Expedition, 2007/08), the research team used a deep ice-penetrating radar system to measure the ice thickness and subglacial topography of the “Chinese Wall” around Kunlun Station, East Antarctica. Preliminary results show that the ice thickness varies mostly from 1600 m to 2800 m along the “Chinese Wall”, with the thickest ice being 3444 m, and the thinnest ice 1255 m. The average bedrock elevation is 1722 m, while the minimum is just 604 m. Compared with the northern side of the ice divide, the ice thickness is a little greater and the subglacial topography lower on the southern side, which is also characterized by four deep valleys. We found no basal freeze-on ice in the Gamburtsev Subglacial Mountains area, subglacial lakes, or water bodies along the “Chinese Wall”. Ice thickness and subglacial topography data extracted from the Bedmap 2 database along the “Chinese Wall” are consistent with our results, but their resolution and accuracy are very limited in areas where the bedrock fluctuates intensely. The distribution of ice thickness and subglacial topography detected by ice-penetrating radar clarifies the features of the ice sheet in this “inaccessible” region. These results will help to advance the study of ice sheet dynamics and the determination of future locations of the GSM’s geological and deep ice core drilling sites in the Dome A region.

Key words： Antarctic Ice sheet Kunlun Station Ice thickness Subglacial topography Ice-penetrating radar

收稿日期: 2014-11-20;

基金资助:

本研究由国家重点基础研究发展计划（编号：2013CBA01804，2012CB957702）、极地环境调查和评估专项（编号：CHINARE-02-02）和国家自然科学基金项目（编号：41201426）联合资助。

引用本文:

崔祥斌,孙波,苏小岗等. 东南极昆仑站周边沿“中国墙”的冰厚和冰下地形分布[J]. 应用地球物理, 2016, 13(1): 209-216.

CUI Xiang-Bin,SUN Bo,SU Xiao-Gang et al. Distribution of ice thickness and subglacial topography of the “Chinese Wall” around Kunlun Station, East Antarctica[J]. APPLIED GEOPHYSICS, 2016, 13(1): 209-216.

[1]	Bell, R. E., Ferraccioli, F., Creyts, T. T., et al., 2011, Widespread persistent thickening of the East Antarctic Ice Sheet by freezing from the base: Science, 331(6024), 1592−1595.
[2]	Cheng, X., Gong, P., Zhang, Y., et al., 2009, Surface topography of Dome A, Antarctica, from differential GPS measurements: Journal of Glaciology, 55(189), 185−187.
[3]	Cui, X., Sun, B., Tian, G., et al., 2010, Ice radar investigation at Dome A, East Antarctica: Ice thickness and subglacial topography: Chinese Science Bulletin, 55(3), 425−431.
[4]	Ding, M., Xiao, C., Li, Y., et al., 2011, Spatial variability of surface mass balance along a traverse route from Zhongshan station to Dome A, Antarctica: Journal of Glaciology, 57(204), 658−666.
[5]	Ferraccioli, F., Finn, C. A., Jordan, T. A., et al., 2011, East Antarctic rifting triggers uplift of the Gamburtsev Mountains: Nature, 479(7373), 388−392.
[6]	Fretwell, P., Pritchard, H. D., Vaughan, D. G., et al., 2012, Bedmap2: improved ice bed, surface and thickness datasets for Antarctica: The Cryosphere, 6(5), 4305-4361.
[7]	Huss, M., and Farinotti, D., 2014, A high-resolution bedrock map for the Antarctic Peninsula: The Cryosphere, 8(1), 1261−1273.
[8]	Jiang, S., Cole-Dai, J., Li, Y., et al., 2012, A detailed 2840 year record of explosive volcanism in a shallow ice core from Dome A, East Antarctica: Journal of Glaciology, 58(207), 65−75.
[9]	Liu, H., Jezek, K. C., Li, B., et al., 2001, RADARSAT Antarctic Mapping Project digital elevation model.
[10]	Ren, J., Xiao, C., and Hou, S., et al., 2009, New focuses of polar ice-core study: NEEM and Dome A: Chinese Science Bulletin, 54(6), 1009−1011.
[11]	Severinghaus, J., Wolff, E., and Brook, E. J., 2010, Searching for the oldest ice: EOS Transactions of the American Geophysical Union, 91(40), 357-358.
[12]	Siegert, M. J., Carter, S., and Tabacco, I., et al., 2005, A revised inventory of Antarctic subglacial lakes: Antarctic Science, 17(3), 453−460.
[13]	Sun, B., Siegert, M. J., Mudd, S. M., et al., 2009, The Gamburtsev mountains and the origin and early evolution of the Antarctic Ice Sheet: Nature, 459(7247), 690−693.
[14]	Sun, B., and Cui, X., 2009, Progress on the expedition of the Chinese Antarctic Dome Argus in 2007/2008: Chinese Journal of Polar Research, 20(4), 371−378.
[15]	Sun, B., Moore, J. C., Zwinger, T., et al., 2014, How old is the ice beneath Dome A, Antarctica: The Cryosphere, 8(3), 1121−1128.
[16]	Wang, T. T., Sun, B., Guan, Z. Q., et al., 2013, Research on radio-echo sounding data processing: a case study at Dome A, Antarctica: Chinese Journal of Polar Research, 25(2), 197−203.
[17]	Yang, Y. D., Sun, B., Wang, Z. M., et al., 2014, GPS-derived velocity and strain fields around Dome Argus, Antarctica: Journal of Glaciology, 60(222), 735−741.
[18]	Young, D. A., Wright, A. P., Roberts, J. L., et al., 2011, A dynamic early East Antarctic Ice Sheet suggested by ice-covered fjord landscapes: Nature, 474(7349), 72−75.

[1]	唐学远，郭井学，孙波，王甜甜，崔祥斌. 东南极冰盖伊丽莎白公主地中国泰山站站址所在区域的冰厚、内部等时层、地表和冰下地形[J]. 应用地球物理, 2016, 13(1): 203-208.