高原气象

高原气象 >

2017 , Vol. 36 >Issue 2: 307 - 316

DOI: https://doi.org/10.7522/j.issn.1000-0534.2016.00120

论文

青藏高原深层土壤热通量的变化特征分析

  • 周亚 ,
  • 高晓清 ,
  • 李振朝 ,
  • 惠小英 ,
  • 杨丽薇
展开
  • 中国科学院寒旱区陆面过程与气候变化重点实验室/中国科学院西北生态环境资源研究院, 兰州 730000;中国科学院大学, 北京 100049

收稿日期: 2016-08-03

  网络出版日期: 2017-04-28

基金资助

国家自然科学基金项目(91437108,41675017)

收起

Analysis of the Characteristics of Deep Soil Heat Flux in Qinghai-Tibetan Plateau

  • ZHOU Ya ,
  • GAO Xiaoqing ,
  • LI Zhenchao ,
  • HUI Xiaoying ,
  • YANG Liwei
Expand
  • Key Laboratory of Land Surface Process and Climate Change in Cold and Arid Regions, Northwest Institute of Eco-Evironment and Resources, Chinese Academy of Sciences, Lanzhou 730000, China;University of Chinese Academy of Sciences, Beijing 100049, China

Received date: 2016-08-03

  Online published: 2017-04-28

Fold

摘要

青藏高原地表热状况不仅对局地天气和气候变化有重要影响,而且还在次季节到季节尺度上对周边特别是下游地区的短期气候变化产生影响,因此日益受到研究者的关注。土壤热扩散率和土壤热通量是决定土壤热状况的两个重要因素。不同于以往的研究,本文利用青藏高原地区1980-2001年39个气象站0.8 m和3.2 m的土壤温度资料,采用热传导对流法计算了0.8~3.2 m深层土壤热扩散率和土壤热通量,分析了它们的年变化和年际变化特征,并分析了深层土壤热通量和高原季风的相关关系,得到了一些有意义的结论。青藏高原深层土壤温度随深度的增加振幅减小、位相延迟;在1980-2001年间,土壤热扩散率的变化总体呈减小趋势;土壤深层热通量年变化与土壤表层热通量的年变化具有相反的相位;总热通量与对流热通量的变化具有相同的相位;深层土壤热通量月平均值在冬季为负值(定义热流向上为正),夏季土壤热通量都为正值。土壤热通量与高原冬季风指数的变化趋势相反,相关系数为-0.53;而与高原夏季风指数变化趋势一致,相关系数为0.58,都通过了95%的显著性检验。这些结论对于促使我们认识高原陆气相互作用是非常有意义的。

关键词: 青藏高原; 土壤热扩散率; 土壤热通量; 高原季风

本文引用格式

周亚 , 高晓清 , 李振朝 , 惠小英 , 杨丽薇 . 青藏高原深层土壤热通量的变化特征分析[J]. 高原气象, 2017 , 36(2) : 307 -316 . DOI: 10.7522/j.issn.1000-0534.2016.00120

Abstract

The surface thermal condition of Qinghai-Tibetan Plateau is not only important for the local weather and climate, but also for the short-term climate change in the surrounding areas, especially in sub-seasonal to seasonal scale. Soil thermal diffusivity and soil heat flux are two key factors to determine soil thermal condition. The spatial and temporal distribution of soil thermal diffusivity and the soil heat flux in Qinghai-Tibetan Plateau are still not well understood. In this paper, the method of Conduction-Convection was applied to calculate the soil thermal diffusivity and the soil heat flux in Qinghai-Tibetan Plateau by using monthly mean soil temperature at the depths of 0.8 m and 3.2 m in 39 meteorological observatories from 1980 to 2001.Their characteristics of annual and inter-annual variations and the relationship between soil heat flux and plateau monsoon were analyzed and got some meaningful conclusions. The results show that the annual amplitude of soil temperature decreases and phase of soil temperature delays with depth. The soil thermal diffusivity appears an overall decreasing trend from 1980 to 2001.The annual variations of soil heat flux have opposite phase between deep and surface. The annual variations of total heat flux and convective heat flux have the same phase. The monthly mean soil heat flux is negative during the winter, and positive in summer. The correlation coefficient between the soil heat flux and plateau winter monsoon index is-0.53.The soil heat flux is consistent with the plateau summer monsoon index, the correlation coefficient between them is 0.58.Both values pass the T-test with significance of α=0.05.These results are valuable for us to understand the plateau air-land interactions.

Key words: Qinghai-Tibetan Plat; Soil thermal diffusi; Soil heat flux; Plateau monsoon

参考文献

[1]Gao Z, Chae N, Kim J.2000.Simulation of surface temperature, water balance and soil wetness in the Tibetan prairie using the simple biosphere Model 2[C][WT《Times New Roman》]//Proceedings of the Second Session of the Inter-nationalWorkshop on TIPEX-GAME/TIBET, Kunming, China.2000: 32-34.
[2]Gao Z Q.2005.Determination of soil host flux in a Tibetan short-grass prairie[J].Bound-Layer Meteor, 114(1): 165-178.
[3]Gao Z, Fan X, Bian L.2003.An analytical solution to one-dimensional thermal conduction-convection in soil[J].Soil Science, 168(2): 99-107.
[4]Gao Z, Wang J, Ma Y, et al.2000.Study of roughness lengths and drag coefficients over Nansha Sea Region, Gobi, desert, oasis and Tibetan Plateau[J].Phys Chem Earth B, 25(2): 141-145.
[5]Krishnamurti T N, Ramanathan Y.1982.Sensitivity of the monsoon onset to differential heating[J].J Atmos Sci, 39(6): 1290-1306.
[6]de Silans A M B P, Monteny B A, Lhomme J P.1996.Apparent soil thermal diffusivity, a case study: HAPEX-Sahel experiment[J].Agricultural and Forest Meteorology, 81(3): 201-216.
[7]Tang Maocang, Gao Xiaoqing.1997.Some statistic characteristics of" Underground Hot Vortex" in China during 1980-1993 (Ⅰ)——Statistic correlation between" Underground Hot Vortex" and earthquake[J].Science in China: Earth Sciences, 40(6): 569-576.
[8]Van Wijk W R.1963.Physics of plant enviroment[M].Amsterdam: North Holland Amsterdam Press, 1-156.
[9]Wu A, Ni Y.1999.The effects of Tibetan Plateau on the anomalous variation of Asian Monsoon in a coupled ocean-atmosphere system[J].Acta Meteor Sinica, 13(1): 21-34.
[10]白虎志, 谢金南, 李栋梁.2001.近40年青藏高原季风变化的主要特征[J].高原气象, 20(1): 22-27.
[11]Bai Huzhi, Xie Jingnan, Li Dongliang.2001.The principal feature of Qinghai-Xizang Plateau monsoon variation in 40 years[J].Plateau Meteor, 20(1): 22-27.
[12]陈芳, 马英芳, 李维强.2005.青海高原太阳辐射时空分布特征[J].气象科技, 33(3): 232-234.
[13]Chen Fang, Ma Yingfang, Li Weiqiang.2005.Distribution characteristics of solar radiation over Qinghai Plateau[J].Meteorogical Science and Technology, 33(3): 232-234.
[14]董文杰, 汤懋苍.1992.用气象站地温资料计算多年平均土壤热流的初步结果[J].高原气象, 11(2): 115-123.
[15]Dong Wenjie, Tang Maocang.1992.The preliminary results of calculating annual mean soil heat flux with temperature data[J].Plateau Meteor, 11(2): 115-123.
[16]范新岗, 汤懋苍.1994.土壤传导-对流通量计算初步结果[J].高原气象, 13(1): 14-19.
[17]Fan Xingang, Tang Maocang.1994.A preliminary study on conductive and convective soil heat flux[J].Plateau Meteor, 13(1): 14-19.
[18]冯松, 汤懋苍, 王冬梅.1988.青藏高原是我国气候变化启动区的新证据[J].科学通报, 43(6): 633-636.
[19]Feng Song, Tang Maocang, Wang Dongmei.1988.The Tibetan Plateau is new evidence of climate change in the promoter region[J].Chinese Science Bulletin, 43(6): 633-636.
[20]高国栋, 陆渝蓉.1981.我国地表面与下层土壤间热交换量的计算和分布[J].地理学报, 36(3): 254-266.
[21]Gao Guodong, Lu Yurong.1981.The calculation and analysis of the heat exchange between the ground surface and the deeper layer of soil in china[J].Acta Geographica Sinica, 36(3): 254-266.
[22]高志球, 卞林根, 张雅斌, 等.2002.土壤传导方程解析解和那曲地区土壤热扩散率研究[J].气象学报, 60(3): 352-360.
[23]Gao Zhiqiu, Bian Lingen, Zhang Yabin, et al.2002.Analytical solution of soil conduction equation and the study of soil thermal diffusivity in Naqu[J].Acta Meteorological Sinica, 60(3): 352-360.
[24]李韧, 赵林, 丁永建, 等.2012.近40a来青藏高原地区总辐射变化特征分析[J].冰川冻土, 34(6): 1319-1327.
[25]Li Ren, Zhao Lin, Ding Yongjian, et al.2012.Variation charateristics of global radiation over the Tibetan plateau during the past 40 years[J].Journal of Glaciology and Geocryology, 34(6): 1319-1327.
[26]马振峰, 高文良.2003.青藏高原季风年际变化与长江上游气候变化的联系[J].高原气象, 22(增刊): 8-15.
[27]Ma Zhenfeng, Gao Wenliang.2003.Relationship between interannual change over Qinghai-Xizang Plateau monsoon and climate change in upper reach of Changjiang river[J].Plateau Meteor, 22(Suppl): 8-15.
[28]马柱国, 魏和林, 符淙斌.2000.中国东部区域土壤湿度的变化与其气候变率的关系[J].气象学报, 58(3): 278-287.
[29]Ma Zhuguo, Wei Helin, Fu Zongbin.2000.Relationship between regional soil moisture variation and climatic variability over east China[J].Acta Meteorological Sinica, 58(3): 278-287.
[30]缪育聪, 刘树华, 吕世华, 等.2012.土壤热扩散率及其温度、热通量计算方法的比较研究[J].地球物理学报, 55(2): 441-451.
[31]Miao Yucong, Liu Shuhua, Lü Shihua, et al.2012.A comparative study of computing methods of soil thermal diffusivity, temperature and heat flux[J].Chinese Journal of Geophysics, 55(2): 441-451.
[32]邵明安, 王全九, 黄明斌.2006.土壤物理学[M].北京:高等教育出版社, 170-175.
[33]Shao Mingan, Wang Quanjiu, Huang Mingbin.2006.Soil physics[M].Beijing: Higher Education Press, 170-175.
[34]汤懋苍, 梁娟, 邵明镜, 等.1984.高原季风年际变化的初步分析[J].高原气象, 3(3): 76-82.
[35]Tang Maocang, Liang Juan, Shao Mingjing, et al.1984.The preliminary analysis of Plateau monsoon interannual variability [J].Plateau Meteor, 3(3): 76-82.
[36]韦志刚, 文军, 吕世华, 等.2005.黄土高原陆-气相互作用预试验及其晴天地表能量特征分析[J].高原气象, 24(4): 545-555.
[37]Wei Zhigang, Wen Jun, Lü Shihua, et al.2005.A primary field experiment of land-atmosphere interaction over the Loess Plateau and its ground surface energy in clear day[J].Plateau Meteor, 24(4): 545-555.
[38]魏东平, 石耀霖, 汤懋苍, 等.1992.利用气象地温资料反演大地热流[J].地球物理学报, 35(6): 732-739.
[39]Wei Dongping, Shi Yaolin, Tang Maocang, et al.1992.Calculation of heat flow from meteorological data[J].Acta Geophysica Sinica, 35(6): 732-739.
[40]温克刚, 陶诗言, 徐祥德, 等, 1999.第二次青藏高原大气科学试验理论研究进展 (一)[M].北京:气象出版社.
[41]Wen Kegang, Tao Shiyan, Xu Xiangde, et al.1999.Progress in theoretical research on the TIPEX (Ⅰ)[M].Beijing: Chinese Meteorological Press.
[42]翁笃鸣, 高庆先, 何凤翩.1994.中国土壤热通量的气候计算及其分布特征[J].气象科学, 14(2): 91-98.
[43]Weng Duming, Gao Qingxian, He Fengpian.1994.Climatologcal calculations and distribution of soil heat flux over china[J].Scientia Meteorological Sinica, 14(2): 91-98.
[44]吴国雄, 段安民, 刘屹岷, 等.2013.关于亚洲夏季风爆发的动力学研究的若干近期进展[J].大气科学, 37(2): 212-227.
[45]Wu Guoxiong, Duan Anming, Liu Yimin, et al.2013.Recent advances in the study on the dynamics of the Asian summer monsoon onset[J].Chinese J Atmos Sci, 37(2): 212-227.
[46]肖志祥, 段安民.2015.孟加拉湾热带风暴对青藏高原降水和土壤湿度的影响[J].中国科学, 45(5): 625-638.
[47]Xiao Zhixiang, Duan Anming.2015.Can the tropical storms originated from the Bay of Bengal impact the precipitation and soil moisture over the Tibetan Plateau[J].Science in China, 45(5): 625-638.
[48]徐祥德, 周明煜, 陈家宜, 等.2001.青藏高原地-气过程动力、热力结构综合物理图像[J].中国科学, 31(5): 428-439.
[49]Xu Xiangde, ZhouMingyu, ChenJiayi, et al.2001.The integrated physical image of dynamic and thermodynamic structure of land-atmosphere process in Qinghai-Tibet Plateau [J].Science in China, 31(5): 428-439.
[50]徐兆生, 马玉堂.1984.青藏高原土壤热通量的测量、计算和气候学推广方法[M].青藏高原气象科学实验文集 (二), 24-34.
[51]Xu Zhaosheng, Ma Yutang.1984.Soil heat flux measurements, calculations and climatology promotion methods in Tibetan Plateau[M].Meteorological Science Experiment Book in Tibetan Plateau (two), 24-34.
[52]杨红娟, 丛振涛, 雷志栋.2009.利用遥测地表温度模拟土壤热通量[J].干旱区研究, 26(1): 21-25.
[53]Yang Hongjuan, Cong Zhentao, Lei Zhidong.2009.Application of harmonic analysis to estimate soil heat flux using remotely measured surface remperature[J].Arid Zone Research, 26(1): 21-25.
[54]杨振刚.1985.土壤热流的计算[J].河北农业大学学报, 8(2): 36-44.
[55]Yang Zhengang.1985.Calculating soil heat flow[J].Journal Publishing Department of Agricultural University of Hebei, 8(2): 36-44.
[56]叶笃正, 罗四维, 朱抱真.1957.西藏高原及其附近的流场结构和对流层大气的热量平衡[J].气象学报, 28(2): 108-120.
[57]Ye Duzheng, Luo Siwei, Zhu Baozhen.1957.The wind structure and heat balance in the lower troposphere over Tibetan Plateau and its surrounding[J].J Meteor Res, 28(2): 108-120.
[58]叶笃正, 曾庆存, 郭裕福.1991.当代气候研究[M].北京:气象出版社.
[59]Ye Duzheng, Zeng Qingcun, Guo Yufu.1991.Study of contemporary climate[M].Beijing: China Meteorological Press.
[60]张宏, 胡波, 刘广仁, 等.2012.中国土壤热通量的时空分布特征研究[J].气候与环境研究, 17(5): 515-521.
[61]Zhang Hong, Hu Bo, Liu Guangren, et al.2012.Temporal and spatial characteristics of soil heat flux in china[J].Climatic and Environmental Research, 17(5): 515-521.
[62]张立杰, 江灏, 李磊.2006.利用气象要素计算五道梁地区土壤热流量的试验[J].高原气象, 25(3): 418-422.
[63]Zhang Lijie, Jiang Hao, Li Lei.2006.Atest of the soil heat flux calculation in Wudaoliang area using meteorological elements[J].Plateau Meteor, 25(3): 418-422.
[64]张立杰, 李磊, 沈永平.2005.基于多时间尺度分析的青藏铁路沿线土壤热流研究[J].物理学报, 54(4): 1958-1963.
[65]Zhang Lijie, Li Lei, Shen Yongping.2005.Analysis of soil heat flux based on the multiple time scale along Qinghai-Tibet railway[J].Chinese Journal of Physics, 54(4): 1958-1963.
[66]张雯, 王磊, 陈权亮.2015.青藏高原东部土壤湿度变化及其与中国降水的关系[J].成都信息工程学院学报, 30(1): 81-85.
[67]Zhang Wei, Wang Lei, Chen Quanliang.2015.The soil moisture in eastern of Qinghai-Tibet Plateau and its relationship with precipitation in china[J].Journal of Chengdu University of Information Technology, 30(1): 81-85.
Options
文章导航

/

本系统由北京玛格泰克科技发展有限公司设计开发 技术支持:support@magtech.com.cn