1.Wang, B.*, Y. Ma*, Z. Su, Y. Wang and W. Ma. Quantifying the evaporation amounts of 75 high-elevation large dimictic lakes on the Tibetan Plateau. Science Advances, 2020, 6, eaay8558. 

2.Wang, B.*, Y. Ma, Y. Wang, Z. Su and W. Ma, 2019. Significant differences exist in lake-atmosphere interactions and the evaporation rates of high-elevation small and large lakes, Journal of Hydrology, 573:220-234.

3.Wang, B.*, Y. Ma*, W. Ma, Z. Su*, and X. Dong, 2019. Evaluation of ten methods for estimating evaporation in a small high-elevation lake on the Tibetan Plateau, Theoretical and Applied Climatology, 136:1033-1045. 

4.Wang, B.*, Y. Ma, W. Ma, and Z. Su, 2017. Physical controls on half-hourly, daily and monthly turbulent flux and energy budget over a high-altitude small lake on the Tibetan Plateau, Journal of Geophysical Research: Atmospheres, 122:2289-2303.

5.Wang. B.*, Y. Ma, X. Chen, W. Ma, Z. Su, and M. Menenti, 2015. Observation and simulation of lake-air heat and water transfer processes in a high-altitude shallow lake on the Tibetan Plateau, Journal of Geophysical Research: Atmospheres, 120:12,327-12,344.

6.Wang. B, Ma Y M*, and Ma W Q, 2012. Estimation of land surface temperature retrieved from EOS/MODIS in Naqu area over Tibetan Plateau. Journal of Remote Sensing, 16:1289-1309.

7.Wang, Y., Yang, K.*, Zhou, X., Wang, B., Chen, D., Lu, H., et al, 2019. The formation of a dry‐belt in the north side of central Himalaya Mountains, Geophysical Research Letters, 46:2993-3000.

8.Wang, Y., Yang, K.*, Zhou, X., Chen D. L., Ouyang, L., Chen, Y. Y., Wang, B. B. 2020. Synergy of orographic drag parameterization and high resolution greatly reduces biases of WRF-simulated precipitation in central Himalaya, Climate Dynamics, 54: 1729-1740.

9.Ram Hari Acharya, Madan Sigdel*, Yaoming Ma*, and Binbin Wang, 2019. Diurnal and seasonal variation of heat fluxes over an agricultural field in southeastern Nepal, Theor Appl Climatol, 137:2949-2960.

10.Joshi, B., Ma Yaoming*，W.Ma, M.Sigdel, B.Wang, S.Subba, 2020, Seasonal and Diurnal Variations of Carbon Dioxide and Energy Fluxes over Three Land Cover Types of Nepal, Theoretical and Applied Climatology, 139:415–430.

11.Luintel,N., W.Ma*, Ma Yaoming, B.Wang, S. Sunil, 2019, Spatial and temporal variation of daytime and nighttime MODIS land surface temperature across Nepal，Atmospheric and Oceanic Science Letters, 12:305-312.

12.Zhang, L., Ma Yaoming*, W. Ma, and B. Wang, 2018, Comparison of different generation mechanisms of free convection between two stations on the Tibetan Plateau. Advances in Atmospheric Sciences, 35:1137-1144.

13.Ma, Y.*, W. Ma, L. Zhong, Z. Hu, M. Li, Z Zhu, C. Han, B. Wang, and X. Liu, 2017. Monitoring and Modeling the Tibetan Plateau’s climate system and its impact on East Asia. Sci. Rep., 7:44574.

14.Fangfang HUANG, W. Ma.*, Binbin WANG, Zeyong HU, Yaoming MA, Genhou SUN, Zhipeng XIE, Yun LIN, 2017. Air Temperature Estimation with MODIS Data over the Northern Tibetan Plateau, Adv. Atmos. Sci., 34:650-662.

15.Ma, N., J. Szilagyi, G.-Y. Niu, Y. Zhang, T. Zhang, B. Wang, and Y. Wu, 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.

16.Amatya, P., Y. Ma*, C. Han, B. Wang, and L. Devkota, 2016. Mapping regional distribution of land surface heat fluxes on the southern side of the central Himalayas using TESEBS, Theor Appl Climatol, 124:835-846.

17.Amatya, P. M., Y. Ma*, C. Han, B. Wang, and L. P. Devkota, 2015. Recent trends (2003-2013) of land surface heat fluxes on the southern side of the central Himalays, Nepal, J. Geophys. Res. Atmos., 120:11,957-11,970.

18.Amatya, P. M., Y. Ma*, C. Han, B. Wang, and L. P. Devkota, 2015. Estimation of net radiation flux distribution on the southern slopes of the central Himalayas using MODIS data, Atmospheric Research, 154:146-154.

19.M. Li*, Wolfgang Babel, X. Chen, L. Zhang, F. Sun, B. Wang, Y. Ma, Z. Hu, Thomas Foken, 2015. A 3-year dataset of sensible and latent heat fluxes from the Tibetan Plateau, derived using eddy covariance measurements, Theor Appl Climatol, 122: 457-469

20.Ma, Y.*, Z. Zhu, L. Zhong, B. Wang, C. Han, Z. Wang, Y. Wang, L. Lu, P. M. Amatya, W. Ma, Z. Hu, 2014. Combining MODIS, AVHRR and in situ data for evapotranspiration estimation over heterogeneous landscape of the Tibetan Plateau, Atmospheric Chemistry and Physics, 14:1507-1515.

21.Ma, Y.*, C. Han, L. Zhong, B. Wang, Z. Zhu, Y. Wang, L. Zhang, C. Meng, C. Xu, and P. Amatya, 2014. Using MODIS and AVHRR data to determine regional surface heating field and heat flux distributions over the heterogeneous landscape of the Tibetan Plateau, Theor Appl Climatol, 117:643-652.

22.Chen X.*, Z. Su, Y.M. Ma, K. Yang, B. Wang, 2013. Estimation of surface energy fluxes under complex terrain of Mt. Qomolangma over the Tibetan Plateau, Hydrol. Earth Syst. Sci., 17:1607-1618.

23.Ma Y.*, B. Wang, L. Zhong, and W. Ma, 2012. The regional surface heating field over the heterogeneous landscape of the Tibetan Plateau using MODIS and in-situ data. Adv. Atmos. Sci., 29:47-53

24.Ma Y.*, L. Zhong, B. Wang, W. Ma, X. Chen, M. Li, 2011. Determination of land surface heat fluxes over heterogeneous landscape of the Tibetan Plateau by using the MODIS and in situ data. Atmos. Chm. Phys, 11:10461-10469.