[1] Y Q Cao, W Zhang, W J Wang et al. Evaluation of TRMM 3B43 data over the Yangtze River Delta of China. Scientific Reports, 8, 5290-5290(2018).

[2] S Cascone, J Coma, A Gagliano et al. The evapotranspiration process in green roofs: A review. Building and Environment, 147, 337-355(2019).

[3] N Chen, X Z Feng, P F Xiao et al. Analysis of snow layer parameters in Manasi River Basin. Journal of Nanjing University(Natural Sciences), 51, 936-943(2015).

[4] R S Chen. Some knowledge on and parameters of China’s alpine hydrology. Advances in Water Science, 25, 307-317(2014).

[5] H Ezzine, A Bouziane, D Ouazar et al. Downscaling of open coarse precipitation data through spatial and statistical analysis, integrating NDVI, NDWI, elevation, and distance from sea. Advances in Meteorology, 99, 1-20(2017).

[6] S F Jia, W B Zhu, A F Lu et al. A statistical spatial downscaling algorithm of TRMM precipitation based on NDVI and DEM in the Qaidam Basin of China. Remote Sensing of Environment, 115, 3069-3079(2011).

[7] M Kronenberg, M Barandun, M Hoelzle et al. Mass-balance reconstruction for Glacier No.354, Tien Shan, from 2003 to 2014. Annals of Glaciology, 57, 92-102(2016).

[8] Y C Lan, Y P Shen, S F Wu et al. Changes of the glaciers and the glacier water resources in the typical river basins on the north and south slopes of the Tianshan Mountains since 1960s. Journal of Arid Land Resources and Environment, 21, 1-8(2007).

[9] B F Li, Y N Chen, Z S Chen et al. Trends in runoff versus climate change in typical rivers in the arid region of northwest China. Quaternary International, 282, 87-95(2012).

[10] K M Li, Z Q Li, W Y Gao. Recent retreat of glaciers in the East Tianshan Mountains of Xinjiang and its impact on water resources. Chinese Science Bulletin, 56, 2708-2716(2011).

[11] Y Li, H Tao, B D Su et al. Impacts of 1.5°C and 2°C global warming on winter snow depth in Central Asia. Science of The Total Environment, 651, 2866-2873(2019).

[12] J D Mackay, N E Barrand, D M Hannah et al. Glacio-hydrological melt and runoff modelling: Application of a limits of acceptability framework for model comparison and selection. The Cryosphere, 12, 2175-2210(2018).

[13] M Y Mcpartland, E S Kane, M J Falkowski et al. The response of boreal peatland community composition and NDVI to hydrologic change, warming and elevated carbon dioxide. Global Change Biology, 25, 93-107(2019).

[14] S Michaelides, T Karacostas, J L Sanchez et al. Reviews and perspectives of high impact atmospheric processes in the Mediterranean. Atmospheric Research, 208, 4-44(2017).

[15] J X Mu, Z Q Li, H Zhang et al. Mass balance variation of continental glacier and temperate glacier and their response to climate change in western China: Taking Urumqi Glacier No.1 and Parlung No.94 Glacier as examples. Arid Land Geography, 42, 20-28(2019).

[16] S Muattar, J L Ding, S Abudu et al. Simulation of snowmelt runoff in the catchments on northern slope of the Tianshan Mountains. Arid Zone Research, 33, 636-642(2016).

[17] K Naegeli, M Huss, M Hoelzle. Change detection of bare-ice albedo in the Swiss Alps. The Cryosphere, 13, 397-412(2019).

[18] Y P Shen, H C Su, G Y Wang et al. The responses of glaciers and snow cover to climate change in Xinjiang (I): Hydrological effects. Journal of Glaciology and Geocryology, 35, 513-527(2013).

[19] Y F Shi. Concise Glacier Inventory of China(2009).

[20] M Smid, A C Costa. Climate projections and downscaling techniques: A discussion for impact studies in urban systems. The International Journal of Urban Sciences, 22, 277-307(2018).

[21] C Q Song, B Huang, L H Ke et al. Precipitation variability in High Mountain Asia from multiple datasets and implication for water balance analysis in large lake basins. Global and Planetary Change, 145, 20-29(2016).

[22] C J Sun, W Chen. Streamflow components in inland rivers in the Tianshan Mountains, Northwest China. Arid Land Geography, 40, 37-44(2017).

[23] D B M R Van, C Bus, J Ettema et al. Temperature thresholds for degree-day modelling of Greenland ice sheet melt rates. Geophysical Research Letters, 37, 1-5(2010).

[24] G Y Wang, Y P Shen. The effect of change in glacierized area on the calculation of mass balance in the Glacier No.1 at the Headwaters of Urumqi River. Journal of Glacilogy and Geocryology, 33, 1-7(2011).

[25] P Y Wang, Z Q Li, H L Li et al. Recent evolution in extent, thickness, and velocity of Haxilegen Glacier No.51, Kuytun River Basin, Eastern Tianshan Mountains. Arctic, Antarctic, and Alpine Research, 48, 241-252(2016).

[26] X Wang, T Yang, C Xu et al. Understanding the discharge regime of a glacierized alpine catchment in the Tianshan Mountains using an improved HBV-D hydrological model. Global and Planetary Change, 172, 211-222(2019).

[27] X C Wang, X B Dong, H M Liu et al. Linking land use change, ecosystem services and human well-being: A case study of the Manas River Basin of Xinjiang, China. Ecosystem services, 27, 113-123(2017).

[28] L H Wu, H L Li, L Wang. Application of a degree-day model for determination of mass balance of Urumqi Glacier No.1, Eastern Tianshan, China. Journal of Earth Science, 22, 470-481(2011).

[29] Z H Xu, W G Fan, H J Wei et al. Evaluation and simulation of the impact of land use change on ecosystem services based on a carbon flow model: A case study of the Manas River Basin of Xinjiang, China. Science of The Total Environment, 652, 117-133(2019).

[30] Z N Yang. Glacier water resources in China. Natural Resources, 9, 46-55(1987).

[31] G Zhang, Z Li, W Wang et al. Mass balance change in east and west branches of Glacier No.1 at Urumqi riverhead, China, during last 20 years. Chinese Journal of Ecology, 32, 2412-2417(2013).

[32] G F Zhang. Glacier matter balance and its relation to climate change at the source of Urumqi River, Tianshan, China. Lanzhou: Northwest Normal University(2014).

[33] H Zhang, Z Q Li, P Zhou et al. Mass-balance observations and reconstruction for Haxilegen Glacier No.51, eastern Tien Shan, from 1999 to 2015. Journal of Glaciology, 64, 689-699(2018).

[34] Q Zhang, P J Shi, V P Singh et al. Spatial downscaling of TRMM-based precipitation data using vegetative response in Xinjiang, China. International Journal of Climatology, 37, 3895-3909(2017).

[35] R B Zhang, W S Wei, H M Shang et al. A tree ring-based record of annual mass balance changes for the TS. Tuyuksuyskiy Glacier and its linkages to climate change in the Tianshan Mountains. Quaternary Science Reviews, 205, 10-21(2019).

[36] S Q Zhang, B S Ye, S Y Liu et al. A modified monthly degree-day model for evaluating glacier runoff changes in China. Part I: Model development. Hydrological Processes, 26, 1686-1696(2012).

[37] T Zhang, B L Li, Y C Yuan et al. Spatial downscaling of TRMM precipitation data considering the impacts of macro-geographical factors and local elevation in the Three-River Headwaters Region. Remote Sensing of Environment, 215, 109-127(2018).

[38] Y Zhang, S Y Liu, C W Xie et al. Application of a degree-day model for the determination of contributions to glacier meltwater and runoff near Keqicar Baqi glacier, southwestern Tien Shan. Annals of Glaciology, 43, 280-284(2006).

[39] J T Zheng. Research on runoff evolution in mountainous area under climate change in Manas River. Shihezi: Shihezi University(2018).

[40] G F Zhu, D H Qin, Y F Liu et al. Accuracy of TRMM precipitation data in the southwest monsoon region of China. Theoretical and Applied Climatology, 129, 1-10(2017).