天山东部冰芯pH 值和电导率的大气环境空间差异
收稿日期: 2008-07-25
修回日期: 2008-11-02
网络出版日期: 2009-01-25
基金资助
国家重点基础研究发展规划项目(2007CB411501);中国科学院知识创新工程重要方向项目 (KZCX2-YW-127);国家自然科学基金项目(40631001;40571033;40701034;40371028;J0630966;40701035); 国家基金委创新群体项目(40121101) 资助
The pH and Electrical Conductivity of Atmospheric Environment from Three Shallow Ice Cores in the Eastern Tianshan Mountains
Received date: 2008-07-25
Revised date: 2008-11-02
Online published: 2009-01-25
Supported by
National Key Project for Basic Research of China, No.2007CB411501;Knowledge Innovation Project of CAS, No.KZCXZ-YW-127;National Natural Science Foundation of China, No. 40631001;No.40571033;No.40701034;No.40371028;No. J0630966;No.40701035. The Project for Outstanding Young Scientists of National Natural Science Foundation of China, No.40121101
冰芯电导率是大气环境变化的替代性指标。对我国天山东部三个研究点奎屯哈希勒根 48 号冰川、乌鲁木齐河源1 号冰川以及哈密庙儿沟平顶冰川粒雪芯中pH 值和电导率的近期环境记录进行了分析研究。结果显示, 三个研究点粒雪芯反映的近期pH 值和电导率变化趋势不同: 奎屯电导率随冰芯深度增加表现出升高趋势, 哈密庙尔沟平顶冰川和乌鲁木齐河源 1 号冰川随冰芯深度增加表现出一定下降趋势; 冰芯电导率平均值在哈密庙儿沟冰川最大, 而其他两个点相对较小, 这与矿物粉尘浓度和离子浓度的分布一致; 雪冰电导率与粉尘及离子相关性分析表明, 电导率主要受中亚粉尘活动影响, 同时与Ca2+、Mg2+、Na+等相关性很高。 通过比较显示, 天山东部与我国西部其他研究点以及极地雪冰电导率的差异可以很好地反映大气环境的空间差异。
董志文,李忠勤,王飞腾,张明军 . 天山东部冰芯pH 值和电导率的大气环境空间差异[J]. 地理学报, 2009 , 64(1) : 107 -116 . DOI: 10.11821/xb200901011
The pH values and Electrical Conductivity Measurement (ECM) records in three shallow ice cores from Glacier No.1 at the headwater of the Urumqi River, Kuitun Glacier No.48 and Hami Miaoergou Glacier in the eastern Tianshan Mountains, western China were measured and analyzed for the research on atmospheric environmental change. Ice core records show that the changing trends of pH and ECM at the three sites in recent about 10 years are different: Kuitun ECM increased with the change of the ice depth, but Hami site and Urumqi Glacier No.1 show a decreasing trend. The average ECM value in Hami is greater than the other two sites, just as the case of high dust concentration and ions concentration at this site. ECM records are mainly affected by Asian dust, as the correlative coefficients of ECM and mineral ions such as Ca2+, Mg2+ and Na+ are significantly high. Also, pH and ECM are significantly high correlative coefficients, which coincide with the research on the Tibetan Plateau, but different from that in the polar regions.
[1] IPCC (2007). Climate change 2007: The Physical Sciences Basis. Contribution of Working Group I to the fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press, 2007. 29-30; 131-132; 153-180.
[2] Taylor K C, Hammer C U, Alley R B et al. Electrical conductivity measurements from the GRIP2 and GRIP Greenland ice cores. Nature, 1993, 366: 549-552.
[3] Delmas R, Briat M, Legrand M. Chemistry of south polar snow. Journal of Geophysical Research, 1982, 87 (C6): 4314-4318.
[4] Delmas R J. Antarctic precipitation chemistry. In: Jaeschke W (ed.). Chemistry of Multiphase Atmospheric System. NATO ASI Series, 1986(G6): 250-256.
[5] Lazrus A L, Ferek R J. Acidic sulfate particles in the winter Arctic atmosphere. Geophysical Research Letters, 1984, 11: 417-419.
[6] Legrand M, Petit J R, Korot Kevich Y S et al. Conductivity of Antarctic ice in relation to its chemistry. Journal of Physique, 1987, (C1): 605-611.
[7] Moore J C, Wolff E W, Hammer C U et al. The chemical basis for the electrical stratigraphy of ice. Journal of Geophysical Research, 1992, 97: 1887-1896.
[8] Moore J C, Wolff E W. Electrical response of the summit Greenland ice core to ammonium, sulphuric acid, and hydrochloric acid. Geophysical Research Letters, 1994, 21(7): 565-568.
[9] Sheng Wenkun, Yao Tandong, Xie Chao et al. Analysis of pH and conductivity in Guliya ice core since little ice age. Journal of Glaciology and Geocryology, 1995, 17(4): 360-365.
[盛文坤, 姚檀栋, 谢超等. 古里雅小冰期以来的pH 值 和电导率分析. 冰川冻土, 1995, 17(4): 360-365.]
[10] Xiao Cunde, Qin Dahe, Ren Jiawen et al. The difference of atmospheric loadings between Antarctic, Arctic and Qinghai-Tibetan Plateau, shown by electrical conductivity of snow and ice. Chinese Journal of Polar Research, 1999, 11(1): 1-7.
[效存德, 秦大河, 任贾文等. 雪冰电导率反映的南、北极与青藏高原大气环境差异. 极地研究, 1999, 11(1): 1-7.]
[11] Hou Shugui, Qin Dahe, Ren Jiawen et al. The present environmental process of the pH and conductivity records in the glacier No.1 at the headwaters of Urumqi River, Tianshan Mountains. Journal of Glaciology and Geocryology, 1999, 21(3): 225-232.
[侯书贵, 秦大河, 任贾文等. 天山乌鲁木齐河源1 号冰川记录的pH 和电导率记录的现代环境过 程. 冰川冻土, 1999, 21(3): 225-232.]
[12] Dong Zhiwen, Li Zhongqin, Wang Feiteng et al. Characteristics of modern atmospheric dust deposition in snow on the glaciers of east Tianshan Mountains, China. Acta Geographica Sinica, 2008, 63(5): 544-552.
[董志文, 李忠勤, 王飞腾 等. 天山东部冰川积雪中大气粉尘的沉积特征. 地理学报, 2008, 63(5): 544-552.]
[13] Li Xiangying, Li Zhongqin, Chen Zhenghua et al. Seasonal variation and elution processes of pH and electrical conductivity in snowpits on Glacier No.1 on Urumqi river head, Tianshan. Advances in Earth Science, 2006, 21(5): 487-495.
[李向应, 李忠勤, 陈正华等. 天山乌鲁木齐河源1 号冰川雪坑中pH 和电导率的季节变化及淋溶过程. 地 球科学进展, 2006, 21(5): 487-495.]
[14] You Xiaoni, Li Zhongqin, Wang Feiteng et al. Seasonal evolution of insoluble micropartical stratigraphy in glacier NO. 1 percolation zone, eastern Tianshan, China. Advances in Earth Science, 2006, 21(11): 1164-1170.
[尤晓妮, 李忠勤, 王飞腾等. 乌鲁木齐河源1 号冰川不溶微粒的季节变化特征. 地球科学进展, 2006, 21(11): 1164-1170.]
[15] Gu Juan, He Yuanqing, Zhang Zhonglin et al. The response of pH value in ice core to precipitation in the Mountain Yulong. Journal of Glaciology and Geocryology, 2005, 27(4): 509-514.
[顾娟, 何元庆, 张忠林等. 玉龙雪山浅冰芯 pH 值对冰川作用区降水量变化的响应. 冰川冻土, 2005, 27(4): 509-514.]
[16] Wang Jian, Aihemaiti Aximu, Ding Yongjian et al. Variations of pH value and electrical conductivity in the Dongkemadi Basin, Tagula Range. Environmental Science, 2007, 28(10): 2301-2306.
[王建, 艾合麦提·阿希木, 丁永 建等. 唐古拉冬克玛底冰川流域pH 值和电导率分析. 环境科学, 2007, 28(10): 2301-2306. ]
[17] Sheng Wenkun, Yao Tandong, Li Yuefang et al. Dry and wet changes in Guliya ice cap region approached by pH and electric conductivity in ice core. Journal of Glaciology and Geocryology, 1998, 20(4): 432-437.
[盛文坤, 姚檀栋, 李月 芳. 用古里雅冰芯的pH 值和电导率探讨该冰川作用区的干湿变化. 冰川冻土, 1998, 20(4): 432-437.]
[18] Wei Wenshou, Gao Weidong, Shi Yuguang et al. Influence of climate and environment change on dust storms in Xinjiang, China. Arid Land Geography, 2004, 27(2): 137-141.
[魏文寿, 高卫东, 史玉光等. 新疆地区气候与环境变 化对沙尘暴的影响研究. 干旱区地理, 2004, 27(2): 137-141.]
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