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干旱区地理 ›› 2017, Vol. 40 ›› Issue (4): 762-771.

• 气候与水文 • 上一篇    下一篇

1979-2016年祁连山地区大气水汽含量时空特征及其与降水的关系

巩宁刚1, 孙美平1,2, 闫露霞1, 宫鹏1, 马兴刚1, 牟建新1   

  1. 1. 西北师范大学地理与环境科学学院, 甘肃 兰州 730070;
    2. 中国科学院西北生态环境资源研究院, 甘肃 兰州 730000
  • 收稿日期:2016-12-24 修回日期:2017-03-10 出版日期:2017-07-25
  • 通讯作者: 孙美平(1982-),女,辽宁沈阳人,副教授,博士,主要从事寒区旱区气候变化及水文过程方面研究.Email:sunmeiping1982@163.com
  • 作者简介:巩宁刚(1992-),男,甘肃平凉人,硕士研究生,研究方向为寒区旱区水文与环境变化.Email:15249306057@163.om
  • 基金资助:

    国家自然科学基金项目(41561016);中国博士后第57批面上资助项目(2015M572619)

Temporal and spatial characteristics of atmospheric water vapor and its relationship with precipitation in Qilian Mountains during 1979-2016

GONG Ning-gang1, SUN Mei-ping1,2, YAN Lu-xia1, GONG Peng1, MA Xing-gang1, MOU Jian-xin1   

  1. 1. College of Geography and Environment Science, Northwest Normal University, Lanzhou 730070, Gansu, China;
    2. Northwest institute of Eco-Environment and Resources, CAS, Lanzhou 730000, Gansu, China
  • Received:2016-12-24 Revised:2017-03-10 Online:2017-07-25

摘要: 采用1979-2016年ECMWF1.5°×1.5°逐月再分析资料及同期37个气象站点的降水资料,利用一元线性回归、累积距平、Kriging及IDW(反距离加权)等方法分析了祁连山地区大气水汽含量时空分布特征、降水转化率空间变化规律以及风场分布规律,并对比分析了中国西部不同地区降水转化率的变化趋势。结果表明:(1)1979-2016年祁连山地区大气水汽含量整体呈增加趋势,且季节变化明显。其中夏季是各层大气水汽含量最多的季节,高达329.24 mm,占多年平均大气水汽含量的48.1%。(2)近38 a来,祁连山地区的大气水汽含量呈东南多、西北少的空间分布,且随海拔的升高而逐渐减少,整层大气水汽主要集中在5 000 m以下。(3)祁连山地区的降水转化率从空间上表现出由东向西递减的趋势,说明该地区空中云水资源的开发潜力自东向西逐渐增强,空中云水资源的开发潜力区域差异明显;季风所携带的水汽对其影响区域的降水贡献率较高,西风所携带的水汽则对其影响区域的降水贡献率较低。(4)中国西部地区降水转化率呈向心式递减的趋势,且区域空间波动较大。

关键词: 祁连山地区, 大气水汽含量, 时空变化, 降水转化率

Abstract: Qilian Mountains region is one of the most important water vapor cycle sites in arid and semi-arid areas of Northwest China,and the most important water vapor regulation area in Hexi Corridor. Based on the monthly reanalysis data of ECMWF 1.5°×1.5° during 1979-2016 and precipitation data of 37 meteorological stations in corresponding period,by adopting approaches of monadic linear regression method,accumulative anomaly,Kriging and IDW,the paper analyzed the spatial-temporal characteristics of atmospheric water vapor content, the spatial changing rule of precipitation conversion rate and the distribution law of wind field in Qilian Mountains,and the change trend of precipitation conversion rate in western China. Results show as follows:(1)The atmospheric water vapor showed an increasing trend in Qilian Mountains and the seasonal variation of atmospheric water vapor content showed a significant increase trend during 1979-2016. Summer had the most atmospheric water vapor in all layers,which was up to 329.24 mm,accounting for more than 48.1% of the annual average atmospheric water vapor content.(2)In recent 38 years,the atmospheric water vapor content in the Qilian Mountains region decreased from southeast to northwest; meanwhile,the water vapor content decreased gradually with the rising of altitude. Atmospheric water vapor of the whole layer mainly concentrated below 5 000 m,and from 875 hPa(about 1 253 m)to 550 hPa(about 5 000 m),the water vapor content accounted for 92.2% of the total water vapor content.(3)The precipitation conversion rate showed a decrease trend from the east to west in Qilian Mountains,with an average rate of 36.2%,a maximum rate of 76.2%,and a minimum rate of 3.8%,indicating that the development potential of the space cloud water resource enhanced gradually from east to west,the region-al difference of developing potential of cloud water resource was obvious. The water vapor carried by the monsoon had a high contribution to the precipitation in the region,while the water vapor carried by the westerly wind had a lower contribution.(4)The precipitation conversion rate showed a decrease trend in a centripetal direction in western China,and the precipitation conversion rates varied in different regions and among different periods.

Key words: Qilian Mountains, atmospheric water vapor content, temporal and spatial variation, precipitation conversion efficiency

中图分类号: 

  • P426