收稿日期: 2005-12-30
修回日期: 2006-01-20
网络出版日期: 2006-02-15
基金资助
北京市自然科学基金项目“北京市建筑立面材料对城市局部热环境的影响”(编号:8062020);国家自然科学基金项目“基于野外观测的沙尘暴源地的下垫面特征和沙尘危险度研究”(编号:40541001)资助.
Soil Water Content Observations Under Different Soil Classification in Central and East Inner Mongolia of China
Received date: 2005-12-30
Revised date: 2006-01-20
Online published: 2006-02-15
以2002—2003年连续两年自行观测的内蒙古中西部地区二连浩特、乌拉特中旗和乌海的土壤水分为基础,重点分析了沙尘暴发生季节反映下垫面特征的土壤水分的时间变化以及大气影响对不同土壤类型(棕钙土,灰漠土,栗钙土)水分的作用。土壤水分的变化被分为3个阶段进行分析,分别是解冻期至沙尘暴开始的春季、雨期的秋季和冰雪覆盖的冬季。土壤水分受气象条件和土壤类型的影响较大。在气象条件的影响下,土壤水分含量在土壤融化期最低,在雨季达到最大值,其中以栗钙土受的影响最明显。沙尘暴发生依赖于土壤融化时间、土壤融化期的土壤条件和上年冬季的冻土深度。
杜子璇 , 李宁 , KevinLevy5 , 任学慧 , 顾卫 , 史培军 . 内蒙古中西部地区不同土壤类型下土壤水分的研究[J]. 地球科学进展, 2006 , 21(2) : 151 -156 . DOI: 10.11867/j.issn.1001-8166.2006.02.0151
Soil water content was observed continuously and automatically in Erlianhaote, Wulatezhongqi and Wuhai, northwestern Inner Mongolia, China for two years (2002-2003) in this paper. Based on the data, the temporal variation of soil water content was analyzed, which represented the characteristics of land surface. The effect on soil water content) influenced by atmosphere in different soil texture (Brown-calcium soil, Chestnut--calcium soil and Gray-desert soil) was compared. Seasonal variations of the soil water content were characterized into three stages, from thawing to active dust storm (spring), rainy (autumn) and snow cover (winter) period. The soil water content much depended on meteorology condition. By these observations, it became clear that the soil water content was the lowest in the beginning thaw period, and was the highest in the rainy season. Differences in soil water content among the years depended on the lowest in the whole thaw period meteorological conditions The soil water content was lowest during the soil melt period, the variations of Chestnut-calcium soil was obvious under meteorology condition. The dust emission much influenced by thaw time of soil, soil wetness and the thaw period and depth of frozen soil.
[1] Gu Wei, Cai Xuepeng, Xie Feng, et al. Study on relationship between vegetation cover and distribution of days of sandstorm—Taking central and western Inner Mongolia for example[J]. Advances in Earth Science,2002, 7(2):273-277. [顾卫,蔡雪鹏,谢锋,等.植被覆盖与沙尘暴日数分布关系的探讨[J].地球科学进展,2002,17(2):273-277.]
[2] Shi Peijun, Zhang Hong, Wang Ping, et al. The regional patterns for combating sandification in sandy disaster affected area in China[J]. Journal of Natural Disasters,2000,9(3):1-7. [史培军,张宏,王平,等.我国防沙治沙的区域模式[J].自然灾害学报,2000,9(3):1-7.]
[3] Li Ning, Gu Wei, Xie Feng, et al. Threshold value response of soil moisture to dust storms—A case study of midwestern of Inner Mongolia[J]. Journal of Natural Disasters,2004,13(1): 44-49. [李宁,顾卫,谢锋,等.土壤水分对沙尘暴的阈值反应——以内蒙古中西部地区为例[J].自然灾害学报,2004,13(1):44-49.]
[4] Bai Jingyu, Shi Xiaoying, Yu Shuqiu. Preliminary research on soil moisture in eastern part of Northwest China[J]. Meteorological Science and Technology,2003,31(4):226-230. [柏晶瑜,施小英,于淑秋.西北地区东部春季土壤湿度变化的初步研究[J].气象科技,2003,31(4):226-230.]
[5] Ning Li, Wei Gu, Kevin Levy J, et al. The utility of Hayashi’s quantification theory for assessment of land surface indices in influence dust storm—A case study in Inner Mongolia China[J]. Atmospheric Environment, 2005, 39(1):119-126.
[6] Hollinger S E, Israd S A. A soil water content climatology of Illinois[J]. Journal of Climate,1994,7:822-833.
[7] Tomoyoshi Hirota, Tatsuaki Kasubuchi. Soil moisture observations under different vegetations in a boreal humid climate[J]. Journal of Japan Socciety Hydrology Water Resources,1996,9(3):233-239.
[8] Vinnikov K Y A, Yeserkepova I B. Soil water content: Empirical data and model results[J]. Journal of Climate, 1991,4:66-79.
[9] Gao Tao, Lijuan Su, Qingxia Ma, et al. Climatic analyses on increasing dust storm frequency in the spring of 2000 and 2001 in Inner Mongolia[J]. International Journal of Climatology,2003,23:1 743-1 755.
[10] Engelstaedter S, Kohfeld K F, Tegen I, et al. Controls of dust emissions by vegetation and topographic depressions an evaluation using dust storms frequency data[J]. Geophysical Research Letters,2003,30:Art.1 289-1 294.
[11] Fan Yida, Shi Peijun, Wang Xiushan, et al. The analysis of typical dust storms in Northern China by remote sensing[J]. Advances in Earth Science,2002,17(2):289-294.[范一大,史培军,王秀山,等.中国北方典型沙尘暴的遥感分析[J].地球科学进展,2002,17(2):289-294.]
[12] Liu H Y, Tian Y H, Ding D. Contributions of different land cover types in Otindag Sandy Land and Bashang area of Hebei Province to the material source of sand stormy weather in Beijing[J]. Chinese Science Bulletin,2003,48(17):1 853-1 856.
[13] Matsuba T, Ding C, Lu L. The utility if Hayashi's quantification theory type 2 for the rapid assessment of the epidemiological survey in the developing countries—In a case of the vaccine coverage survey in Yunnan province, China[J]. Journal of Epidemiology,1998,8(1):24-27.
[14] Natsagdory L, Jugder D, Chung Y S. Analysis of dust storms observed in Mongolia during 1937-1999[J]. Atmosphere Environment,2003,37(9):1 401-1 411.
[15] Nilgun K, Slobodan N. An illustration of the transport and deposition of mineral dust onto the eastern Mediterranean[J]. Atmospheric Environment,2000,34:1 293-1 303.
[16] Tegen T, Werner M, Harrison S P, et al. Kohfeld, Relative importance of climate and land use in determining present and future global soil dust emission[J]. Geophysical Research Letters,2004,31:L05105.
[17] Van Douk S J, Skidmore E L. Measurement and simulation of wind erosion, roughness degradation and residue decomposition on an agricultural field[J]. Land Surface Processes and Forms,2003,28(11):1 243-1 258.
[18] Yoshino M. Climatology of yellow sand (Asian sand, Asian dust or Kosa) in East Asia[J]. Science in China(D), 2002,45:59-70.
[19] Zhang X Y, Arimoto R, An Z S. Dust emission from Chinese desert liked to variations in atmospheric circulation[J]. Journal of Geophysical Research-Atmosphere,1997,102(D23):28 041-28 047.
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