Study on Water Internal Recycle Process and Mechanism in Typical Mountain Areas of Inland Basins, Northwest China: Progress and Challenge
First author:Ding Yongjian(1958-),male, Tianshui City, Gansu Province, Professor. Research areas include climate change, hydrology and environment in cold regions. E-mail:dyj@lzb.ac.cn
Received date: 2018-01-05
Revised date: 2018-06-11
Online published: 2018-08-30
Supported by
Project supported by the National Natural Science Foundation of China “Study on water internal recycle processes and mechanism in typical mountain areas of inland basins, Northwest China” (No.41730751) and “Study on ice volume changes and its impact on water resource in upper reach of Shule River basin”(No.41671056).
Copyright
The water resource and its change of mountainous area are very important to the oasis economic system and ecosystem in the arid areas of northwest China. Accurately understanding the water transfer and circulation process among vegetation, soil, and atmosphere over different hydrological units in mountainous areas such as snow and ice, cold desert, forest and grassland is the basic scientific issue of water research in cold and arid regions, which is also the basis of water resource delicacy management and regulation. There are many research results on the hydrological function of different land covers in mountain areas, basin hydrological processes, however, there are only very limited studies on the water internal recycle at basin scale. The quantitative study on the mechanism of water internal recycle is still at the starting stage, which faces many challenges. The key project “Study on water internal recycle processes and mechanism in typical mountain areas of inland basins, Northwest China” funded by National Natural Science Foundation of China will select the Aksu River and Shule River Basin, which have better observation basis, as study area. The internal mechanism of moisture transfer and exchange process of different land cover and atmosphere, the internal mechanism of water cycle in the basin, and water transfer paths in atmosphere will be studied through enhancing runoff plot experiments on different land cover, analyzing the mechanism of water vapor transfer and exchange between different land covers in the watershed by isotope tracing on the water vapor flux of vegetation water, soil moisture and atmospheric moisture, improving the algorithms of remote sensing inversion and ground verification on land surface evapotranspiration on different land cover, and analyzing the water vapor flux from reanalysis data, and the coupling modeling of regional climate model and land surface process model. At last, the effect of different land cover in hydrological process of mountain area, and the impact of land cover on downstream oasis will be systematically analyzed.
Key words: Internal recycle; Mountain basin; Observation; Isotope; Simulation.
Yongjian Ding , Shiqiang Zhang . Study on Water Internal Recycle Process and Mechanism in Typical Mountain Areas of Inland Basins, Northwest China: Progress and Challenge[J]. Advances in Earth Science, 2018 , 33(7) : 719 -728 . DOI: 10.11867/j.issn.1001-8166.2018.07.0719
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