46.Zhang, T. Zhang Y., Guo, Y., Ma N, W., Dai D., Song H., Qu D., Gao H. 2019. Controls of stable isotopes in precipitation on the central Tibetan Plateau: A
seasonal perspective.  Quaternary International, 513, 66-79.[PDF]


45.Ma, N., Szilagyi, J., Zhang, Y., Liu, W. 2019. Complementary-relationship-based modeling of terrestrial evapotranspiration across China during 1982-2012: Validations and spatiotemporal analyses. Journal of Geophysical Research: Atmospheres, 124, doi: 10.1029/2018JD029580.[PDF]


44. Zhu L., Wang J., Ju J., Ma N., Zhang Y., Liu C., Han B., Liu L., Wang M., Ma Q. 2019. Climatic and lake environmental changes in the Serling Co region of Tibet over a variety of timescales. Science Bulletin,64, 422-424.[PDF]


43. Guo Y., Zhang Y., Ma N., Xu J., Zhang T. 2019. Long-term changes in evaporation over Siling Co Lake on the Tibetan and its impact on recent rapid lake expansion. Atmospheric Research, 216, 141-150.[PDF]

42. 王邺凡, 余武生, 张寅生, 张腾, 高海峰, MUHAMMAD Atif Wazir. 2019. 印度河上游 Bagrot 山谷降水稳定同位素变化及与水汽来源的关系. 干旱区地理. 42 (2), 252-262.[PDF]


41. 余坤伦,张寅生, 马宁, 郭燕红. 2018.GPM 和 TRMM 遥感降水产品在青藏高原 中部的适用性评估. 干旱区研究. 35(6), 1373-1381.[PDF]


40. Guo Y., Zhang Y., Zhang T., Wang K., Ding J., Gao H. 2018. Surface Runoff. In: Li X., Vereecken H. (eds) Observation and Measurement of Ecohydrological Processes. Ecohydrology. Springer, Berlin, Heidelberg. DOI: https//doi.org/10.1007/978-3-662-47871-4_8-2.[PDF]


39. Farhan S., Zhang Y., Aziz A., Gao H., Ma Y., Kazmi J., Shahzad A., Hussain I.,Mansha M., Umar M., Nasir J., Shafiq M., Farhan Y., Shaikh S., Zamir U., Asad F., Ahmed R. 2018. Assessing the impacts of climate change on the high altitude snow- and glacier-fed hydrological regimes of Astore and Hunza, the sub-catchments of Upper Indus Basin.Journal of Water and Climate Change, 107, 1-10.[PDF]


38. Ding J., Zhang Y.,Guo Y., Ma N. 2018. Quantitative comparison of river inflows to a rapidly expanding lake in central Tibetan Plateau. Hydrological Processes, 32, 3242-3253.[PDF]


37. Zhang Y., Ma N. 2018. Spatiotemporal variability of snow cover and snow water equivalent in the last three decades over Eurasia. Journal of Hydrology, 559, 238-251.[PDF]


36. Ma N., Niu G-Y., Xia Y., Cai X., Zhang Y., Ma Y., Fang Y. 2017. A systematic evaluation of Noah-MP in simulation land atmosphere energy, water and carbon

exchanges over the continental United States. Journal of Geophysical Research, Atmospheres,122, 12245-12268.[PDF]


35. Ebrahimi S., Chen C., Chen Q., Zhang Y., Ma N., Zaman Q. 2017. Effects of temporal scales and space mismatches on the TRMM 3B42 v7 precipitation product in a remote mountainous area. Hydrological Processes,31,4315-4327.[PDF]


34. Ma N., Zhang Y. 2017. Comment on “Rescaling the complementary relationship for land surface evaporation” by R. Crago et al. Water Resources Research,53, 6340-6342.DOI:10.1002/2017WR020892.[PDF]


33. Zhou J., Wang L,Zhang Y., Guo Y., He D. 2016. Spatiotemporal variations of actual evapotranspiration over the Lake Selin Co and surrounding small lakes (Tibetan Plateau) during 2003–2012. Science China: Earth Sciences, 59(12), 2441-2453. DOI:10.1007/s11430-016- 0023-6.[PDF]


32.Stephan G., Renate F., Emilie G., Prajjwal P., Marc S., Dorothea S., Philippus W., Zhang Y., and Zhao L. 2017. Review article: Inferring permafrost and permafrost thaw in the mountains of the Hindu Kush Himalaya region. The Cryosphere,11, 81-99. DOI:10.5194/tc-11-81-2017.[PDF]


31. Guo Y., Zhang Y., Ma N., Song H, Gao H, 2016. Quantifying surface energy fluxes and evaporation over a significant expanding endorheic lake in the central Tibetan Plateau. Journal of the Meteorological Society of Japan, 94(5), 453-456. DOI:10.2151/jmsj.2016-023.[PDF]


30. Ma N., Szilagyi J., Niu G., Zhang Y., Zhang T., Wang B, Wu Y, 2016. Evaporation variability of Nam Co Lake in the Tibetan Plateau and its role in recent rapid lake expansion. Journal of Hydrology, 537, 27-35. DOI:org/10.1016/j.jhydrol.2016.03.030.[PDF]


29. Zhou J., Wang L., Zhang Y., Guo Y., Li X, and Liu W. 2015. Exploring the water storage changes in the largest lake (Selin Co) over the Tibetan Plateau during 2003–2012 from a basin-wide hydrological modeling. Water Resources Research,51(10), 1-27. DOI:10.1002/2014WR015846.[PDF]


28. Ma N., Zhang Y., Guo Y., Gao H., Zhang H., Wang Y. 2015. Environmental and biophysical controls on the evapotranspiration over the highest alpine steppe. Journal of Hydrology, 529(3), 980-992. DOI:10.1016/j.jhydrol.2015.09.013.[PDF]


27. Ma N., Zhang Y., Xu C., Szilagyi J. 2015. Modeling actual evapotranspiration with routine meteorological variables in the data-scarce region of the Tibetan Plateau:Comparisons and implications. Journal of Geophysical Research: Biogeosciences, 120, 1638-1657. DOI:10.1002/2015JG003006.[PDF]


26. Ma Y., Zhang Y., Zubrzycki S., Guo Y., Farhan S. 2015. Hillslope-scale variability in seasonal frost depth and soil water content investigated by GPR on the southern margin of the sporadic permafrost zone on the Tibetan Plateau. Permafrost and Periglacial Processes,26, 321-334. DOI:10.1002/ppp.1844.[PDF]


25. 张寅生, 马颖钊, 张艳林, 高海峰, 翟建青. 2015. 青藏高原坡面尺度冻融循环与水热条件空间分布. 科学通报, 60(7), 664-673.[PDF]


24. 周婷, 张寅生, 高海峰, 张腾, 马颖钊. 2015. 青藏高原高寒草地植被指数变化与地表温度的相互关系. 冰川冻土, 37(1), 58-69.[PDF]


23. Ma N., Zhang Y., Szilagyi J., Guo Y., Zhai J., Gao H. 2015. Evaluating the complementary relationship of evapotranspiration in the alpine steppe of the Tibetan Plateau. Water Resources Research, 51, 1069–1083. DOI:10.1002/2014WR015493.[PDF]


22. Farhan S., Zhang Y., Ma Y., Guo Y., Ma N. 2015. Hydrological regime under conjunction of westerly and monsoon climate, a case investigation of Astore Basin, Northwestern Himalaya. Climate Dynamics, 44,3015-3032. DOI:10.1007/s00382-014-2409-9.[PDF]


21. Ma Y., Zhang Y., Yang D., Farhan S. 2015. Precipitation bias variability versus various gauges under different climatic conditions over the Third Pole Environment(TPE) region. International Journal of Climatology,35(7), 1201–1211.DOI:10.1002/joc.4045. [PDF]


20. Song H., Zhang Y., Gao H., Guo Y., Li S. 2014. Plateau wetlands, an indispensible habitat for the Black-Necked Crane (Grus nigricollis)-A review. Wetlands, 34(4), 629-639.[PDF]


19. 郭燕红, 张寅生, 马颖钊, 马宁. 2014. 藏北羌塘高原双湖地表热源强度及地表水热平衡. 地理学报, 69(7),983-992.[PDF]


18. Ma Y., Zhang Y., Farhan S., Guo Y. 2012. Permafrost soil water content evaluation using high-frequency ground-penetrating radar in Amdo catchment, Central Tibetan Plateau. IEEE Ground Penetrating Radar (GPR) 14th International Conference, Doi:10.1109/ICGPR.2012.6254940.[PDF]


17. Zhang Y., Yao T., Ma Y. 2012. Climatic changes have led to significant expansion of endorheic lakes in Xizang(Tibet) since 1995. Scinences in Cold and Arid Regions,3(6), 463-467.[PDF]


16. 张寅生, 马颖钊, 郭燕红, Farhan Suhaib Bin. 2012. 青藏高原50年来水循环要素变化趋势及其趋势差异性. 第四纪研究, 32(1),95-102.[PDF]


15. Zhang Y., Guo Y. 2011. Variability of atmospheric freezing-level height and its impact onthe cryosphere in China. Annals of Glaciology, 52(58), 81-88.[PDF]


14. Zhang Y., GUO Y. 2011. Water cycle changes during the past 50 years over the Tibetan Plateau: Review and synthesis. IAHS Publ. 346.[PDF]


13. Zhang Y., Ohata T., Zhou J., Davaa G. 2011. Modelling plant canopy effects on annual variability of evapotranspiration and heat fluxes for a semi-arid grassland on the southern periphery of the Eurasian cryosphere in Mongolia. Hydrological Processes, 25, 1201- 1211.[PDF]


12. Zhang Y., Ishikawa M., Ohata T., Oyunbaatar D. 2008. Sublimation from thin snow cover at the edge of the Eurasian cryosphere in Mongolia. Hydrological Processes, 22, 3564-3575.[PDF]

11. Zhang Y., Kadota T., Ohata D. 2007. Oyunbaatar.Environmental controls on evapotranspiration from sparse grassland in Mongolia. Hydrological Processes, 110, 2016-2027.[PDF]


10. M Ishikawa., Zhang Y., T Kadota.. and Tetsuo Ohata. 2006. Hydrothermal regimes of dry active layer. Water Resources Research, 42, DOI:10.1029/2005


9. Zhang Y., Munkhtsetseg E., Kadota T., Ohata T., 2005. An observational study of ecohydrology of a sparse grassland at the edge of the Eurasian cryosphere in Mongolia.Journal of Geophysical Research Atmospheres, 110, D14103. DOI:10.1029/ 2004JD005474.[PDF]

8. Zhang Y., K Suzuki., T Kadota., T Ohata. 2004. Sublimation from snow surface in southern mountain Taiga of eastern Siberia.Journal of Geophysical Research Atmospheres, 109, No.D21103.[PDF]

7. Zhang Y., T Ohata., Yang D and G Davaa. 2004. Bias correction of daily precipitation measurements for Mongolia. Hydrological Processes, 18, 2991-3005.[PDF]

6. Zhang Y., T Ohata., Kang Ersi., Yao T. 2003. Observation and Estimation of Evaporation from the Ground Surface of the Cryosphere in Eastern Asia. Hydrological Processes, 17, 1135-1147.[PDF]

5. Zhang Y., T Ohata., T Kadota. 2003. Land-surface hydrological processes in the permafrost region of the eastern Tibetan Plateau, Journal of Hydrology, 283, 41-56.[PDF]

4. Zhang Y., T Kadota., T Ohata. 2003. Land-Surface Hydrological Processes in Discontinues Permafrost Region of the Western Tibet Plateau. ICOP2003, Permafrost (2), 1295-1300.[PDF]

3. Zhang Y., T Ohata., H Hirashima. 2002. Spatial Distribution of Surface Soil Moisture and Evaporation in a Small Watershed of Tiksi, Eastern Siberia. J. Japan Soc. Hydrol.& Water Resourc, 15(5), 486-495. [PDF]

2. Zhang W., Zhang Y., K Ogawa., Y Yamaguchi. 1999. Observation and estimation of daily actual evapotranspiration and evaporation on a glacierized watershed at the headwater of the Urumuqi River, Tianshan, China. Hydrological Processes, 13, 1589-1061.[PDF]


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