Spatio-temporal pattern and attribution analysis of the mass elevation effect in the Tianshan Mountains in China

• Published in: Journal of geographical sciences Vol. 33; no. 10; pp. 2031 - 2051
• Main Authors: Zhang, Mingyu, Zhang, Zhengyong, Liu, Lin, Zhang, Xueying, Kang, Ziwei, Chen, Hongjin, Gao, Yu, Wang, Tongxia, Yu, Fengchen
• Format: Journal Article
• Language: English
• Published: Heidelberg Science Press 01.10.2023; Springer; Springer Nature B.V
• Subjects: Altitude; Analysis; Earth and Environmental Science; Ecological effects; Elevation; Geographical Information Systems/Cartography; Geography; Geospatial data; Heterogeneity; Mountain regions; Mountains; Nature Conservation; Physical Geography; Precipitation; Precipitation (Meteorology); Remote sensing; Remote Sensing/Photogrammetry; Temperature inversions; Topography; Tien Shan Mountains; China; spatial downscaling; GWR; Tianshan Mountains; mass elevation effect; GeoDetector
• ISSN: 1009-637X; 1861-9568
• DOI: 10.1007/s11442-023-2164-0

The mass elevation effect (MEE) is a thermal effect, in which heating produced by long wave radiation on a mountain surface generates atmospheric uplift, which has a profound impact on the hydrothermal conditions and natural geographical processes in mountainous areas. Based on multi-source remote sensing data and field observations, a spatial downscaling inversion of temperature in the Tianshan Mountains in China was conducted, and the MEE was estimated and a spatio-temporal analysis was conducted. The GeoDetector model (GDM) and a geographically weighted regression (GWR) model were applied to explore the spatial and temporal heterogeneity of the study area. Four key results can be obtained. (1) The temperature pattern is complex and diverse, and the overall temperature presented a pattern of high in the south and east, but low in the north and west. There were clear zonal features of temperature that were negatively correlated with altitude, and the temperature difference between the internal and external areas of the mountains. (2) The warming effect of mountains was prominent, and the temperature at the same altitude increased in steps from west to east and north to south. Geomorphological units, such as large valleys and intermontane basins, weakened the latitudinal zonality and altitudinal dependence of temperature at the same altitude, with the warming effect of mountains in the southern Tianshan Mountains. (3) The dominant factors affecting the overall pattern of the MEE were topography and location, among which the difference between the internal and external areas of the mountains, and the absolute elevation played a prominent role. The interaction between factors had a greater influence on the spatial differentiation of mountain effects than single factors, and there was a strong interaction between terrain and climate, precipitation, the normalized difference vegetation index (NDVI), and other factors. (4) There was a spatial heterogeneity in the direction and intensity of the spatial variation of the MEE. Absolute elevation was significantly positively correlated with the change of MEE, while precipitation and the NDVI were dominated by negative feedback. In general, topography had the largest effect on the macroscopic control of MEE, and coupled with precipitation, the underlying surface, and other factors to form a unique mountain circulation system and climate characteristics, which in turn enhanced the spatial and temporal heterogeneity of the MEE. The results of this study will be useful in the further analysis of the causes of MEE and its ecological effects.