教育經(jīng)歷

2001/09-2004/06  北京大學物理學院大氣科學系，博士

1998/09-2001/07  蘭州大學資源環(huán)境學院大氣科學系，碩士

1994/09-1998/07  蘭州大學大氣科學系，學士

工作經(jīng)歷

2021/11至今           北京大學城市與環(huán)境學院，教授

2018/06-2021/03  北京師范大學科研院，副院長兼科學技術處處長

2011/01-2021/10  北京師范大學全球變化與地球系統(tǒng)科學研究院，教授，首席科學家（其中2013/12-2021/09任副院長）

2009/12-2010/12   美國德克薩斯大學奧斯汀分校地質(zhì)系，Research Scientist Associate V

2006/07-2009/11   美國馬里蘭大學帕克分校地理系，博士后、助理研究教授

2004/06-2007/06   中國科學院大氣物理研究所，助理研究員

雜志任職

Geophysical Research Letters, editor

榮譽與獎勵

北京師范大學高等教育教學成果獎，二等獎，2021

北京師范大學最受研究生歡迎的十佳教師，2021

北京師范大學課程思政建設優(yōu)秀課程獎，2021

教育部長江學者獎勵計劃特聘教授，2018

北京高校優(yōu)秀共產(chǎn)黨員，2017

第十四屆中國青年科技獎，2016

國家杰出青年科學基金獲得者，2015

北京師范大學十佳師德標兵，2014

北京師范大學優(yōu)秀共產(chǎn)黨員，2014

氣候變化原理與監(jiān)測預估（本科生課程）

氣候變化研究數(shù)據(jù)工具和方法（研究生課程）

國家重點研發(fā)計劃項目，中國東北區(qū)域陸—氣跨圈層精細化協(xié)同觀測和資料反演，2022-2027，項目負責人

國家重點研發(fā)計劃項目，全球變化驅(qū)動下陸表自然與人文要素相互作用及區(qū)域表現(xiàn)，2017-2022，項目負責人

國家自然科學基金重點項目，中國陸表氣候觀測數(shù)據(jù)的漸變型不均一性，2020-2024，項目負責人

國家杰出青年科學基金，地表能量平衡與氣候變化，2016-2020，項目負責人

1. Zhang, Yan, and Kaicun Wang*(2024), The changing morphology of global precipitation systems during the last two decades, Bulletin of the American Meteorological Society, 105(10): E1861-E1880.

2. Zhao, Runze, Kaicun Wang*, and Xiangde Xu (2024), Global precipitation from FY-3 polar orbit satellites, Science Bulletin, 69(17): 2688-2692.

3. Xia, Hanmeng, and Kaicun Wang*(2024), PreciDBPN: A customized deep learning approach for hourly precipitation downscaling in eastern China, Atmospheric Research, 311, 107705.

4. Fu, Kaiqi, Hongyong Yu, Yao Zhang, Dan Zhu, Hongyan Liu, and Kaicun Wang* (2024), Flash drought and heatwave compound events increased in strength and length from 1980 to 2022 in China, Weather and Climate Extremes, 46,100720.

5. Chen, Linghong, and Kaicun Wang*(2024), Sampling error of mean and trend of nighttime air temperature at weather stations over China using satellite data as proxy. Journal of Geophysical Research: Atmospheres, 129, e2023JD039914.

6. Hao, Hongfei, Kaicun Wang*, Guocan Wu, Jianbao Liu, and Jing Li (2024), PM2.5 concentrations based on near-surface visibility in the Northern Hemisphere from 1959 to 2022, Earth System Science Data, 16(9), 4051–4076.

7. Li, Dongpu, Hongli Liu*, Jianbao Liu, Jing Li, and Kaicun Wang* (2024), Impacts of anthropogenic emissions and open biomass burning in South Asia and Southeast Asia on air quality and meteorology over southern China, Journal of Geophysical Research: Atmospheres, 129, e2024JD041267.

8. Zhao, Runze, Kaicun Wang*, and Xiangde Xu (2024), A machine learning method to retrieve global rainfall and snowfall rates from the passive microwave observations of FY-3E, Journal of Geophysical Research: Atmospheres, 129(14), e2024JD040731.

9. Hao, Hongfei, Kaicun Wang*, Chuanfeng Zhao, Guocan Wu, and Jing Li (2024), Visibility-derived aerosol optical depth over global land from 1959 to 2021, Earth System Science Data, 16(7), 3233-3260.

10. Zhang, Zhengtai, and Kaicun Wang*(2024), Quantify uncertainty in historical simulation and future projection of surface wind speed over global land and ocean. Environmental Research Letters, 19(5): 054029.

11. 王開存*，王燦，李龍輝，汪濤，吳國燦，付永碩，馬倩，張井勇，蔡聞佳，曹靜，喻朝慶，朱華晟，南卓銅，陳旻，張晶，紀多穎，沈妙根，唐文君，何斌，占文鳳（2024），陸表自然和人文要素相互作用——全球變化及應對重點專項研究進展，大氣科學學報，47(1): 1-22.

12. Mao, Yuna, Jiaxin Bai, Guocan Wu, Lin Xu, Changjian Yin, Fei Feng, Yanyi He, Zhengtai Zhang, and Kaicun Wang*(2024), Terrestrial evapotranspiration over China from 1982 to 2020: Consistency of multiple data sets and impact of input data. Journal of Geophysical Research: Atmospheres, 129(3), e2023JD039387.

13. Wu, Guocan, Pengfei Lv, Yuna Mao, and Kaicun Wang*(2024), ERA5 Precipitation over China: Better Relative Hourly and Daily Distribution than Absolute Values, Journal of Climate, 37(05): 1581-1596.

14. Feng, Fei, Xin Yang, Baoquan Jia, Xiaoting Li, Xianwen Li, Chengyang Xu*, and Kaicun Wang*(2024), Variability of urban green space and its driving factors in 328 cities in China, Science China Earth Sciences, 67(02): 466-482.

15. 馮飛, 楊鑫, 賈寶全, 李曉婷, 李獻文, 徐程揚*, 王開存*(2024), 中國328個城市的植被覆蓋度長期變化特征及其驅(qū)動因子, 中國科學：地球科學，54(02): 486-502.

16. Yu, Kexing, and Kaicun Wang*(2024), Diurnal to decadal variability in land surface and air temperature gradient from 2002 to 2022 over the contiguous United States, Journal of Climate, 37(04): 1155-1180.

17. Fu, Kaiqi, and Kaicun Wang*(2023), Contributions of local land?atmosphere coupling and mesoscale atmospheric circulation to the 2013 extreme flash drought and heatwave compound event over southwest China, Journal of Geophysical Research: Atmospheres, 128(21): e2023JD039406.

18. Zhang, Yan, Runze Li, and Kaicun Wang*(2023), Climatology and changes in internal intensity distributions of global precipitation systems over 2001-2020 based on IMERG, Journal of Hydrology, 620: 129386.

19. Zhang, Zhengtai, and Kaicun Wang*(2023), Homogenization of observed surface wind speed based on geostrophic wind theory over China from 1970 to 2017, Journal of Climate, 36(11): 3667-3679.

20. Zhang, Yan, and Kaicun Wang*(2023), Mapping the representativeness of precipitation measurements in Mainland China, Environmental Research Letters, 18, 024019.

21. Zhang, Yan, and Kaicun Wang*(2023), Global precipitation system scale increased from 2001 to 2020, Journal of Hydrology, 616:128768.

22. 王開存*，袁慧玲（2023），國家自然科學基金大氣科學學科二級申請代碼下設研究方向與關鍵詞解讀：D0515應用氣象學，大氣科學，47(1): 230-238.

23. 蔡鴻澤，王開存*（2022），基于最新觀測和大氣再分析估計全球能量平衡，科學通報，67(35): 4263-4280.

24. Fu, Kaiqi, and Kaicun Wang*(2022), Quantifying flash droughts over China from 1980 to 2017，Journal of Geophysical Research: Atmospheres, 127(24): e2022JD037152.

25. Li, Runze, Dan Qi, Yan Zhang, Kaicun Wang*(2022), A new pixel-to-object method for evaluating the capability of the GPM IMERG product to quantify precipitation systems, Journal of Hydrology, 2022, 613: 128476.

26. Du, Jizeng, Kaiqi Fu, Baoshan Cui, Kaicun Wang*(2022), Anthropogenic Influences on 2020 Extreme Dry–Wet Contrast over South China, Bulletin of the American Meteorological Society, 103(3): S68-S74.

27. Ma, Qian, Kaicun Wang*, Yanyi He, Liangyuan Su, Qizhong Wu, Han Liu, and Youren Zhang (2022), Homogenized century-long surface incident solar radiation over Japan, Earth System Science Data, 14, 463-477.

28. Mao, Yuna, Guocan Wu, Guangzhi Xu, Kaicun Wang*(2022), Reduction in precipitation seasonality in China from 1960 to 2018, Journal of Climate, 35(1), 227-248.

29. Zhang, Zhengtai, and Kaicun Wang*(2021), Quantifying and adjusting the impact of urbanization on the observed surface wind speed over China from 1985 to 2017, Fundamental Research, 1(6), 785-791.

30. Wu, Guocan, Yun Li, Shun Qin, Yuna Mao, and Kaicun Wang*(2021), Precipitation Unevenness in Gauge Observations and Eight Reanalyses from 1979 to 2018 over China, Journal of Climate, 34(24), 9797–9810.

31. Zhao, Zhe, and Kaicun Wang*(2021), Capability of Existing Drought Indices in Reflecting Agricultural Drought in China, Journal of Geophysical Research: Biogeosciences, 126(8): e2020JG006064.

32. Zhang, Xin, Kaicun Wang*, and Georgiy Kirillin (2021), An automatic method to detect lake ice phenology using MODIS daily temperature imagery, Remote Sensing, 13(14): 2711.

33. Zhang, Yan, and Kaicun Wang* (2021), Global precipitation system size, Environmental Research Letters, 16(5): 054005.

34. Wu, Guocan, and Kaicun Wang* (2021), Observed response of precipitation intensity to dew point temperature over the contiguous US, Theoretical and Applied Climatology, 144: 1349–1362.

35. He, Yanyi, and Kaicun Wang*, and Fei Feng (2021), Improvement of ERA5 over ERA-Interim in simulating surface incident solar radiation throughout China, Journal of Climate, 34(10): 3853–3867.

36. Zhang, Zhengtai, and Kaicun Wang* (2021), The synoptic to decadal variability in the winter surface wind speed over China by the weather regime view, Geophysical Research Letters, 48(6): e2020GL091994.

37. Feng, Fei, and Kaicun Wang* (2021), Merging ground-based sunshine duration observations with satellite cloud and aerosol retrievals to produce high-resolution long-term surface solar radiation over China, Earth System Science Data, 13(3): 907-922.

38. Feng, Fei, and Kaicun Wang* (2021), Merging high-resolution satellite surface radiation data with meteorological sunshine duration observations over China from 1983 to 2017, Remote Sensing, 13(4): 602.

39. Li, Runze, Kaicun Wang*, and Dan Qi (2021), Event-Based Evaluation of the GPM Multi-satellite Merged Precipitation Product from 2014 to 2018 over China: Methods and Results, Journal of Geophysical Research: Atmospheres, 126(1): e2020JD033692.

40. Du, Jizeng, Kaicun Wang*, and Baoshan Cui (2021), Attribution of the extreme drought-related risk of wildfires in spring 2019 over Southwest China, Bulletin of the American Meteorological Society, 102(1): S83-S90.

41. He, Yanyi, Kaicun Wang*, and Dan Qi (2021), Roles of anthropogenic forcing and natural variability in the record-breaking low sunshine event in January-February 2019 over the Middle-Lower Yangtze Plain, Bulletin of the American Meteorological Society, 102(1): S75- S81.

42. Jiang, Shaojing, Kaicun Wang*, and Yuna Mao (2020), Rapid local urbanization around most meteorological stations explain the observed daily asymmetric warming rates across China from 1985 to 2017, Journal of Climate, 33(20): 9045–9061.

43. Du, Jizeng, Kaicun Wang*, Baoshan Cui, Shaojing Jiang, Correction of inhomogeneities in observed land surface temperatures over China, Journal of Climate, 33(20): 8885–8902.

44. He, Yanyi, and Kaicun Wang*(2020), Contrast patterns and trends of lapse rates calculated from near-surface air and land surface temperatures in China from 1961 to 2014, Science Bulletin, 65: 1217-1224.

45. He, Yanyi, and Kaicun Wang*(2020), Variability in direct and diffuse solar radiation across China From 1958 to 2017, Geophysical Research Letters, 47, e2019GL084570.

46. Zhang, Xin, Kaicun Wang* and Bertram Boehrer (2020), Variability in observed snow depth over China from 1960 to 2014, International Journal of Climatology, 40: 3161-3178.

47. An, Ning, Rachel Pinker, Kaicun Wang*, Eric Rogers, and Zhiyan Zuo (2020), Evaluation of Cloud Base Height in the North American Regional Reanalysis Using Ceilometer Observations, International Journal of Climatology, 40: 3161-3178.

48. Chen, Ziyue, Danlu Chen, Chuanfeng Zhao, Mei-po Kwan, Jun Cai, Yan Zhuang, Bo Zhao, Xiaoyan Wang, Bin Chen, Jing Yang, Ruiyuan Li, Bin He, Bingbo Gao, Kaicun Wang*, and Bing Xu* (2020), Influence of meteorological conditions on PM2.5 concentrations across China: A review of methodology and mechanism, Environmental International, 139: 105558.

49. Zhang, Zhengtai, and Kaicun Wang* (2020), Stilling and Recovery of the Surface Wind Speed Based on Observation, Reanalysis, and Geostrophic Wind Theory over China from 1960 to 2017, Journal of Climate, 33: 3989-4008.

50. Zhang, Xin, Kaicun Wang*, Marieke A. Frassl and Bertram Boehrer (2020), Reconstructing six decades of surface temperatures at a shallow lake, Water, 12: 405.

51. Du, Jizeng, Kaicun Wang*, Baoshan Cui, Shaojing Jiang, and Guochan Wu (2020), Attribution of the record-breaking consecutive dry days in winter 2017/18 in Beijing, Bulletin of the American Meteorological Society, 101: S95-S101.

52. Feng, Fei, and Kaicun Wang* (2019), Determining factors of monthly to decadal variability in surface solar radiation in China: evidences from current reanalyses, Journal of Geophysical Research: Atmospheres, 124, 9161–9182.

53. Zhang, Zhengtai, and Kaicun Wang*, Deliang Chen, Jianping Li, and Robert Dickinson (2019), Increase in surface friction dominates the observed surface wind speed decline during 1973-2014 in the Northern Hemisphere lands, Journal of Climate, 32, 7421-7435.

54. Jiang, Shaojing, Xuhui Lee, Jiankai Wang, and Kaicun Wang* (2019), Amplified urban heat islands during heat wave periods, Journal of Geophysical Research: Atmospheres, 124, 7797–7812.

55. Du, Jizeng, Kaicun Wang*, Shaojing Jiang, and Baoshan Cui (2019), Urban dry island effect mitigated urbanization effect on observed warming in China, Journal of Climate, 32, 5705-5723.

56. Feng, Fei, and Kaicun Wang* (2019), Does the MERRA-2 aerosol reanalysis introduce an improvement in the simulation of surface solar radiation over China?, International Journal of Climatology, 39(3):1305-1318.

57. Zhou, Chunlüe, Kaicun Wang*, Dan Qi, Jianguo Tan (2019), Attribution of a record-breaking heatwave event in summer 2017 over the Yangtze River Delta, Bulletin of the American Meteorological Society, 100, S97-S103.

58. Jiang, Shaojing, and Kaicun Wang* (2018), Exploring the holiday effect on air temperatures, Scientific Reports, 8:17943.

59. Li, Runze, Kaicun Wang*, and Dan Qi (2018), Validating the integrated multi-satellite retrievals for global precipitation measurement in terms of diurnal variability with hourly gauge observations collected at fifty thousand stations in China, Journal of Geophysical Research: Atmospheres, 123(18): 10,423-10,442.

60. Zhou, Chunlüe, Yanyi He, and Kaicun Wang*(2018), On the suitability of current atmospheric reanalyses for regional warming studies over China, Atmospheric Chemistry and Physics, 18(11): 8113–8136.

61. He, Yanyi, Kaicun Wang*, Chunlüe Zhou, and Martin Wild (2018), A Revisit of Global Dimming and Brightening Based on the Sunshine Duration, Geophysical Research Letters, 45(9): 4281-4289.

62. Du, Jizeng, Kaicun Wang*, Jiankai Wang, Shaojing Jiang, and Chunlüe Zhou (2018), Diurnal Cycle of Surface Air Temperature within China in Current Reanalyses: Evaluation and Diagnostics, Journal of Climate, 31(11): 4585–4603.

63. Wang, Xiaoyan, Robert E. Dickinson, Liangyuan Su, Chunlüe Zhou, and Kaicun Wang* (2018), PM2.5 pollution in China and how it has been exacerbated by terrain and meteorological conditions, Bulletin of the American Meteorological Society, 99(1): 105-119.

64. Feng, Fei, and Kaicun Wang* (2018), Merging satellite retrievals and reanalyses to produce global long-term and consistent surface incident solar radiation datasets, Remote Sensing, 10(1): 115.

65. Zhou, Chunlüe, Kaicun Wang*, and Dan Qi (2017), Attribution of the July 2016 extreme precipitation event over China’s Wuhan, Bulletin of the American Meteorological Society, 98(12): S107-S112.

66. Zhou, Chunlüe, Kaicun Wang*, and Qian Ma (2017), Evaluation of eight current reanalyses in simulating land surface temperature from 1979 to 2003 in China, Journal of Climate, 30(18): 7379-7398.

67. Zhou, Chunlüe, and Kaicun Wang* (2017), Contrasting Daytime and Nighttime Precipitation Variability between Observations and Eight Reanalysis Products from 1979 to 2014 in China, Journal of Climate, 30: 6443-6464.

68. An, Ning, Kaicun Wang*, Chunlüe Zhou, and Rachel T. Pinker (2017), Observed Variability of Cloud Frequency and Cloud-Base Height within 3600m above the Surface over the Contiguous United States, Journal of Climate, 30: 3725-3742.

69. Zhou, Chunlüe, and Kaicun Wang* (2017), Quantifying the Sensitivity of Precipitation to the Long-Term Warming Trend and Interannual–Decadal Variation of Surface Air Temperature over China, Journal of Climate, 30: 3687-3703.

70. Du, Jizeng, Kaicun Wang *, J. Wang, and Q. Ma (2017), Contributions of surface solar radiation and precipitation to the spatiotemporal patterns of surface and air warming in China from 1960 to 2003, Atmospheric Chemistry and Physics, 17: 4931-4944.

71. Mao, Yuna, and Kaicun Wang * (2017), Comparison of evapotranspiration estimates based on the surface water balance, modified Penman-Monteith model, and reanalysis data sets for continental China, Journal of Geophysical Research: Atmospheres, 122: 3228–3244.

72. Wang*, Kaicun, S. Jiang, C. Zhou, and J. Wang (2017), Comparing the diurnal and seasonal variabilities of atmospheric and surface urban heat islands based on the Beijing urban meteorological network, Journal of Geophysical Research: Atmospheres, 122: 2131–2154.

73. Zhou, Chunlüe, and Kaicun Wang * (2016), Land surface temperature over global deserts: Means, variability, and trends, Journal of Geophysical Research: Atmospheres, 121: 14,344–14,357.

74. Wang, Xiaoyan, and Kaicun Wang *, and L. Su (2016), Contribution of atmospheric diffusion conditions to the recent improvement in air quality in China, Scientific Reports, 6: 36404.

75. Mao, Yuna, Kaicun Wang *, C. Liu and X. Liu (2016), Water Storage in Reservoirs Built from 1997 to 2014 Significantly Altered the Calculated Evapotranspiration Trends over China, Journal of Geophysical Research: Atmospheres, 121(17): 10,097–10,112.

76. Zhou, Chunlüe, and Kaicun Wang * (2016), Spatiotemporal Divergence of Warming Hiatus over Land Based on Mean Temperature of Different Definitions, Scientific Reports, 6: 31789

77. Wang, Xiaoyan, and Kaicun Wang * (2016), Homogenized Variability of Radiosonde-Derived Atmospheric Boundary Layer Height over the Global Land Surface from 1973 to 2014, Journal of Climate, 29(19): 6893-6908.

78. Guo, Li, and Kaicun Wang * (2016), Variability of Tornado Occurrence over the Continental United States since 1950, Journal of Geophysical Research: Atmospheres, 121(12): 6943–6953.

79. Zhou, Chunlüe, and Kaicun Wang * (2016), Coldest Temperature Extreme Monotonously Increased and Hottest Extreme Oscillated over Northern Hemisphere Land during Last 114 Years, Scientific Reports, 6: 25721.

80. Zhou, Chunlüe, and Kaicun Wang * (2016), Evaluation of surface fluxes in ERA‐Interim using flux tower data, Journal of Climate, 29(4): 1573-1582

81. Guo, Li, N. An, and Kaicun Wang * (2016) Reconciling the Discrepancy in Ground- and Satellite-Observed Trends in the Spring Phenology of Winter Wheat in China from 1993 to 2008, Journal of Geophysical Research: Atmospheres, 121(3): 1027–1042

82. Li, Z., Kaicun Wang *, C. Zhou, and L. Wang (2016). Modelling the true monthly mean temperature from continuous measurements over global land, International Journal of Climatology, 36(4): 2103-2110

83. Zhou, Chunlüe, and Kaicun Wang * (2016), Biological and Environmental Controls on Evaporative Fractions at AmeriFlux Sites, Journal of Applied Meteorology and Climatology, 55(1): 145-161.

84. Ma, Q., Kaicun Wang *, M. Wild (2015), Impact of geolocations of validation data on the evaluation of surface incident shortwave radiation from earth system models, Journal of Geophysical Research: Atmospheres, 120 (14): 6825–6844.

85. Wang*, Kaicun, Q. Ma, Z. Li, and J. Wang (2015), Decadal Variability of Surface Incident Solar Radiation over China: Observations, Satellite Retrievals, and Reanalyses, Journal of Geophysical Research: Atmospheres, 120: 6500–6514.

86. Wang*, Kaicun, and Chunlüe Zhou (2015), Regional Contrasts of the Warming Rate over Land Significantly Depend on the Calculation Methods of Mean Air Temperature, Scientific Reports, 5: 12324.

87. An, N., and Kaicun Wang* (2015), A comparison of MODIS-derived cloud amount with surface observations at five SURFRAD sites, Journal of Applied Meteorology and Climatology, 54 (5): 1009-1020.

88. Wang, L. and Kaicun Wang* (2015), Impacts of DEM uncertainty of estimated solar radiation and extracted river network, Bulletin of the American Meteorological Society, 96: 297-304.

89. Wang*, Kaicun (2014), Measurement biases explain discrepancies between observed and simulated decadal variability of surface incident solar radiation, Scientific Reports, 4: 6144.

90. Wang*, Kaicun, Q. Ma, X. Wang, and M. Wild (2014), Urban impacts on mean and trend of surface incident solar radiation, Geophysical Research Letters, 41(13): 4664–4668.

91. Wang, X., and Kaicun Wang* (2014), Estimation of atmospheric mixing layer height from radiosonde data, Atmospheric Measurement Techniques, 7: 1701–1709.

92. Ma, Q., Kaicun Wang*, and M. Wild (2014), Evaluations of atmospheric downward longwave radiation from 44 coupled general circulation models of CMIP5, Journal of Geophysical Research: Atmospheres, 119(8): 4486-4497.

93. Wang*, Kaicun (2014), Sampling biases in datasets of historical mean air temperature over land, Scientific Reports, 4: 4637.

94. Wang*, Kaicun, and R. E. Dickinson (2013), Global atmospheric downward longwave radiation at the surface from ground-based observations, satellite retrievals, and reanalyses, Reviews of Geophysics, 51: 150–185.

95. Wang*, Kaicun, and R. E. Dickinson (2013), Contribution of solar radiation to decadal temperature variability over land, Proceedings of National Academy of Science of the United States of America, 110(37): 14877–14882.

96. Wang*, Kaicun, R. E. Dickinson, Q. Ma, J. A. Augustine, and M. Wild (2013), Measurement methods affect the observed global dimming and brightening, Journal of Climate, 26(12): 4112-4120.

97. Wang*, Kaicun, R. E. Dickinson, M. Wild, S. Liang (2012),Atmospheric impacts on climatic variability of surface incident solar radiation, Atmospheric Chemistry and Physics, 12(20): 9581-9592.

98. Wang*, Kaicun, R. E. Dickinson, L. Su, and K. E. Trenberth (2012), Contrasting trends of mass and optical properties of aerosols over the Northern Hemisphere from 1992 to 2011, Atmospheric Chemistry and Physics,12(19): 9387-9398.

99. Wang*, Kaicun, R. E. Dickinson, and S. L. Liang (2012), Global atmospheric evaporative demand over and from 1973 to 2008, Journal of Climate, 25(23): 8353-8361.

100.Wang*, Kaicun, and R. E. Dickinson (2012), A review of global terrestrial evapotranspiration: observation, modeling, climatology, and climatic variability, Reviews of Geophysics, 50: RG2005.

101.Wang*, Kaicun, J. Augustine, and R. E. Dickinson (2012), Critical assessment of surface incident solar radiation observations collected by SURFRAD, USCRN and AmeriFlux networks from 1995 to 2011, Journal of Geophysical Research: Atmospheres, 117: D23105.

102.Wang*, Kaicun, S. Liang, C. L. Schaaf, and A. H. Strahler (2010), Evaluation of moderate resolution imaging spectroradiometer land surface visible and shortwave albedo products at FLUXNET sites, Journal of Geophysical Research: Atmospheres, 115: D17107.

103.Wang*, Kaicun, R. E. Dickinson, M. Wild, and S. Liang (2010), Evidence for decadal variation in global terrestrial evapotranspiration between 1982 and 2002: 1. method development, Journal of Geophysical Research: Atmospheres, 115: D20112.

104.Wang*, Kaicun, R. E. Dickinson, M. Wild, and S. Liang (2010), Evidence for decadal variation in global terrestrial evapotranspiration between 1982 and 2002: 2. Results, Journal of Geophysical Research: Atmospheres, 115: D20113.

105.Wang*, Kaicun, R. E. Dickinson, and S. Liang (2009), Clear sky visibility has decreased over land globally from 1973 to 2007, Science, 323: 1468-1470.

106.Wang*, Kaicun, and S. Liang (2009), Estimation of daytime net radiation from shortwave radiation measurements and meteorological observations, Journal of Applied Meteorology and Climatology, 48: 634-643.

107.Wang*, Kaicun, and S. Liang (2009), Evaluation of ASTER and MODIS land surface temperature and emissivity products using long-term surface longwave radiation observations at SURFRAD sites, Remote Sensing of Environment, 113: 1556-1565.

108.Wang*, Kaicun, and S. Liang (2009), Global atmospheric downward longwave radiation over land surface under all-sky conditions from 1973 to 2008, Journal of Geophysical Research: Atmospheres, 114: D19101.

109.Wang*, Kaicun, and S. Liang (2008), An improved method for estimating global evapotranspiration based on satellite determination of surface net radiation, vegetation index, temperature, and soil moisture, Journal of Hydrometeorology, 9(4): 712-727.

110.Wang*, Kaicun, R. E. Dickinson, and S. Liang (2008), Observational evidence on the effects of clouds and aerosols on net ecosystem exchange and evapotranspiration, Geophysical Research Letters, 35: L10401.

111.Wang*, Kaicun, P. Wang, Z. Li, M. Cribb, and M. Sparrow (2007), A simple method to estimate actual evapotranspiration from a combination of net radiation, vegetation index, and temperature, Journal of Geophysical Research: Atmospheres, 112: D15107.

112.Wang*, Kaicun, Z. Wan, P. Wang, J. Liu, and M. Sparrow (2007), Evaluation and improvement of the MODIS land surface temperature/emissivity products using ground-based measurements at a semi-desert site on the western Tibetan Plateau, International Journal of Remote Sensing, 28: 2549-2565.

113.Wang*, Kaicun, J. Wang, P. Wang, M. Sparrow, J. Yang, and H. Chen (2007), Influences of urbanization on surface characteristics as derived from the Moderate-Resolution Imaging Spectroradiometer: A case study for the Beijing metropolitan area, Journal of Geophysical Research: Atmospheres, 112: D22S06.

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