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Journal of Arid Land
Research Articles     
Temporal and spatial variation of annual mean air temperature in arid and semiarid region in northwest China over a recent 46 year period
ShaoYong CHEN, YuanYuan SHI, YuZhen GUO, YanXiang Zheng
1 Key Laboratory of Arid Climatic Changing and Reducing Disaster of Gansu, Key laboratory of Arid Climatic Changing and Reducing Disaster of CMA, Institute of Arid Meteorology, CMA, Lanzhou 730020, China; 2 Meteorological Bureau of Baiyin, Baiyin 730900, China
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Abstract  We analyzed the 1961–2006 mean surface air temperature data of 138 stations in China’s northwest arid and semi-arid areas (CNASA), to measure climate change in terms of annual mean air temperature changes. We used methods of linear regression analysis, multinomial fitting, Empirical Orthogonal Function (EOF), Rotated Empirical Orthogonal Function (REOF), Mann-Kendall, Glide T-examination, wavelet analysis and power spectrum analysis. The results show that (1) the warming rate of the annual mean air temperature in CNASA was 0.35oC/10a during the 1961–2006 study period. Some places in the west part of Xinjiang and east part of the Qinghai plateau, which is impacted by the terrain of leeward slope, exhibit smaller increasing trends. However, the majority of region has shown distinct warming in line with general global warming; (2) The standard deviation of the annual mean temperature distribution is non-uniform. The south Xinjiang and east Qinghai–south Gansu areas show relatively small standard deviations, but the inter-annual variation in annual mean air temperature in the greater part of the region is high; (3) Inner Mongolia, Shaanxi, Gansu, Ningxia and Tarim Basin are the areas where the temperature changes are most sensitive to the environment. The degree of uniformity in annual mean air temperature increase is higher in the arid and semi-arid area. From the early 1970s, the trend in temperature changed from a decrease to an increase, and there was a marked increase in mean temperature in 1986. After that mean temperature went through a period of rapid increase. The entire area’s 10 hottest years all occurred in or since the 1990s, and 90% of various sub-districts’ hottest years also occurred after 1990. The process of temperature change appears to have a roughly 5-year and a 10-year cycle; (4) Annual mean air temperature variation has regional differences. In Inner Mongolia–Xinjiang and Shaanxi– Gansu–Ningxia–Qinghai areas, the temperature variation in their northern areas was very different from that in their southern areas; (5) Using the REOF method we divided the region into 4 sub-regions: the Northern region, the Plateau region, the Southern Xinjiang region and the Eastern region. The region’s annual mean air temperature transition has regional differences. The Plateau and Southern Xinjiang regions got warmer steadily without any obvious acceleration in the rate of warming. The Northern region’s warming started about 5-years earlier than that of the low latitude Eastern region. The ‘Startup region’ of the Qinghai-Tibet Plateau, appears to undergo temperature changes 3 to 10 years earlier than the other regions, and exhibits inter-decadal variations 1 to 2 years ahead of the other regions.

Key wordsresource capture efficiency      niche differentiation      root proliferation      resource depletion zone     
Received: 24 December 2009      Published: 07 June 2010
Corresponding Authors: ShaoYong CHEN     E-mail:
Cite this article:

ShaoYong CHEN, YuanYuan SHI, YuZhen GUO, YanXiang Zheng. Temporal and spatial variation of annual mean air temperature in arid and semiarid region in northwest China over a recent 46 year period. Journal of Arid Land, 2010, 2(2): 87-97.

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