发表论文
[1] Shan LU, Zeyong HU, Haipeng YU, Weiwei FAN, Chunwei FU, Di WU. Changes of Extreme Precipitation and its Associated Mechanisms in Northwest China. ADVANCES IN ATMOSPHERIC SCIENCES[J]. 2021, 38(10): 1665-1681, http://dx.doi.org/10.1007/s00376-021-0409-3.[2] 樊威伟, 胡泽勇, 荀学义, 杨耀先, 于海鹏, 付春伟, 吴笛. 青藏高原季风演变及其气候效应综述. 高原气象[J]. 2021, 1294-1303, https://t.cnki.net/kcms/detail?v=3uoqIhG8C44YLTlOAiTRKibYlV5Vjs7iJTKGjg9uTdeTsOI_ra5_XfHHQegN7tNqDjcvNUT78_VAzwBJhKvu-NfbPzxFtpZI&uniplatform=NZKPT.[3] Fan, Weiwei, Ma, Weiqiang, Hu, Zeyong, Ma, Yaoming. Recovery of sensible heating and its elevation amplification over and around the Tibetan Plateau since 2000s. THEORETICAL AND APPLIED CLIMATOLOGY[J]. 2021, 146(1-2): 617-630, http://dx.doi.org/10.1007/s00704-021-03737-3.[4] 马耀明, 胡泽勇, 王宾宾, 马伟强, 陈学龙, 韩存博, 李茂善, 仲雷, 谷良雷, 孙方林, 赖悦, 刘莲, 谢志鹏, 韩熠哲, 袁令, 姚楠, 石兴东. 青藏高原多圈层地气相互作用过程研究进展和回顾. 高原气象. 2021, https://t.cnki.net/kcms/detail?v=3uoqIhG8C46NmWw7YpEsKHTPvOGrUOOqX1coEOzL8AEhGWiDMwILd80Y1vt46NmzENyNTxda2r_57-iJuT4ERrrA8kjn16kK.[5] Yanyan Qin, Zhang Xiaofang, Jan F Adamowski, Asim Biswas, Nicholas M Holden, Zeyong Hu. Grassland grazing management altered soil properties and microbial β-diversity but not α-diversity on the Qinghai-Tibetan Plateau. Applied Soil Ecology[J]. 2021, 167: http://dx.doi.org/10.1016/j.apsoil.2021.104032.[6] Sun, Genhou, Hu, Zeyong, Ma, Yaoming, Xie, Zhipeng, Yang, Song, Wang, Jieming. Analysis of local land-atmosphere coupling in rainy season over a typical underlying surface in Tibetan Plateau based on field measurements and ERA5. ATMOSPHERIC RESEARCH[J]. 2020, 243: http://dx.doi.org/10.1016/j.atmosres.2020.105025.[7] Luo, Qi, Wen, Jun, Hu, Zeyong, Lu, Yaqiong, Yang, Xianyu. Parameter Sensitivities of the Community Land Model at Two Alpine Sites in the Three-River Source Region. JOURNAL OF METEOROLOGICAL RESEARCH[J]. 2020, 34(4): 851-864, http://lib.cqvip.com/Qikan/Article/Detail?id=7102919666.[8] Sun, Genhou, Hu, Zeyong, Ma, Yaoming, Xie, Zhipeng, Wang, Jiemin, Yang, Song. Simulation analysis of local land atmosphere coupling in rainy season over a typical underlying surface in the Tibetan Plateau. HYDROLOGY AND EARTH SYSTEM SCIENCES[J]. 2020, 24(12): 5937-5951, https://doaj.org/article/3542e78cc78c4565a4f45bbfccc2e379.[9] Ma, Yaoming, Hu, Zeyong, Xie, Zhipeng, Ma, Weiqiang, Wang, Binbin, Chen, Xuelong, Li, Maoshan, Zhong, Lei, Sun, Fanglin, Gu, Lianglei, Han, Cunbo, Zhang, Lang, Liu, Xin, Ding, Zhangwei, Sun, Genhou, Wang, Shujin, Wang, Yongjie, Wang, Zhongyan. A long-term (2005-2016) dataset of hourly integrated land-atmosphere interaction observations on the Tibetan Plateau. EARTH SYSTEM SCIENCE DATA[J]. 2020, 12(4): 2937-2957, https://www.webofscience.com/wos/woscc/full-record/WOS:000592857100002.[10] 胡泽勇. 近56 年我国极端降水事件的时空变化格局. 高原气象. 2020, [11] 郑汇璇, 胡泽勇, 孙根厚, 谢志鹏, 严晓强, 王奕丹, 付春伟. 那曲高寒草地总体输送系数及地面热源特征. 高原气象[J]. 2019, 38(3): 497-506, http://lib.cqvip.com/Qikan/Article/Detail?id=7002299823.[12] 严晓强, 胡泽勇, 孙根厚, 谢志鹏, 王奕丹, 郑汇璇. 那曲高寒草地长时间地面热源特征及其气候影响因子分析. 高原气象[J]. 2019, 38(2): 253-263, http://lib.cqvip.com/Qikan/Article/Detail?id=7001897695.[13] Xie, Zhipeng, Hu, Zeyong, Ma, Yaoming, Sun, Genhou, Gu, Lianglei, Liu, Shuang, Wang, Yidan, Zheng, Huixuan, Ma, Weiqiang. Modeling Blowing Snow Over the Tibetan Plateau With the Community Land Model: Method and Preliminary Evaluation. JOURNAL OF GEOPHYSICAL RESEARCH-ATMOSPHERES[J]. 2019, 124(16): 9332-9355, https://www.webofscience.com/wos/woscc/full-record/WOS:000490762800025.[14] Sun, Genhou, Hu, Zeyong, Wang, Jiemin, Ma, Weiqiang, Gu, Lianglei, Sun, Fanglin, Xie, Zhipeng, Yan, Xiaoqiang. The spatial heterogeneity of land surface conditions and its influence on surface fluxes over a typical underlying surface in the Tibetan Plateau. THEORETICAL AND APPLIED CLIMATOLOGY[J]. 2019, 135(1-2): 221-235, [15] Zhong, Lei, Ma, Yaoming, Hu, Zeyong, Fu, Yunfei, Hu, Yuanyuan, Wang, Xian, Cheng, Meilin, Ge, Nan. Estimation of hourly land surface heat fluxes over the Tibetan Plateau by the combined use of geostationary and polar-orbiting satellites. ATMOSPHERIC CHEMISTRY AND PHYSICS[J]. 2019, 19(8): 5529-5541, https://doaj.org/article/71195df5c5fb4b2fabe5e050b2d73580.[16] Hu Zeyong, Xie Zhipeng. Origin and advances in implementing blowing-snow effects in the Community Land Model. Sciences in Cold and Arid Regions[J]. 2019, 11(5): 335-339, http://lib.cqvip.com/Qikan/Article/Detail?id=7100161530.[17] 王奕丹, 胡泽勇, 孙根厚, 谢志鹏, 严晓强, 郑汇璇, 付春伟. 高原季风特征及其与东亚夏季风关系的研究. 高原气象[J]. 2019, 38(3): 518-527, http://lib.cqvip.com/Qikan/Article/Detail?id=7002299825.[18] Wang, Hui, Hu, Zeyong, Li, Dongliang, Dai, Yifei. Estimation of the surface heat transfer coefficient over the east-central Tibetan Plateau using satellite remote sensing and field observation data. THEORETICAL AND APPLIED CLIMATOLOGY[J]. 2019, 138(1-2): 169-183, [19] Yang, Yaoxian, Liu, Yimin, Li, Maoshan, Hu, Zeyong, Ding, Zhangwei. Assessment of reanalysis flux products based on eddy covariance observations over the Tibetan Plateau. THEORETICAL AND APPLIED CLIMATOLOGY[J]. 2019, 138(1-2): 275-292, [20] 徐丽娇, 胡泽勇, 赵亚楠, 洪潇宇. 1961—2010年青藏高原气候变化特征分析. 高原气象[J]. 2019, 38(5): 911-919, http://lib.cqvip.com/Qikan/Article/Detail?id=7100203001.[21] Xie, Zhipeng, Hu, Zeyong, Xie, Zhenghui, Jia, Binghao, Sun, Genhou, Du, Yizhen, Song, Haiqing. Impact of the snow cover scheme on snow distribution and energy budget modeling over the Tibetan Plateau. THEORETICAL AND APPLIED CLIMATOLOGY[J]. 2018, 131(3-4): 951-965, https://www.webofscience.com/wos/woscc/full-record/WOS:000423574800008.[22] Zhao, Ping, Xu, Xiangde, Chen, Fei, Guo, Xueliang, Zheng, Xiangdong, Liu, Liping, Hong, Yang, Li, Yueqing, La, Zuo, Peng, Hao, Zhong, Linzhi, Ma, Yaoming, Tang, Shihao, Liu, Yimin, Liu, Huizhi, Li, Yaohui, Zhang, Qiang, Hu, Zeyong, Sun, Jihua, Zhang, Shengjun, Dong, Lixin, Zhang, Hezhen, Zhao, Yang, Yan, Xiaolu, Xiao, An, Wan, Wei, Liu, Yu, Chen, Junming, Liu, Ge, Zhaxi, Yangzong, Zhou, Xiuji. THE THIRD ATMOSPHERIC SCIENTIFIC EXPERIMENT FOR UNDERSTANDING THE EARTH-ATMOSPHERE COUPLED SYSTEM OVER THE TIBETAN PLATEAU AND ITS EFFECTS. BULLETIN OF THE AMERICAN METEOROLOGICAL SOCIETY[J]. 2018, 99(4): 757-776, http://ir.itpcas.ac.cn/handle/131C11/8685.[23] Yamamoto, Yuhei, Ishikawa, Hirohiko, Oku, Yuichiro, Hu, Zeyong. An Algorithm for Land Surface Temperature Retrieval Using Three Thermal Infrared Bands of Himawari-8. JOURNAL OF THE METEOROLOGICAL SOCIETY OF JAPAN[J]. 2018, 96B: 59-76, https://www.webofscience.com/wos/woscc/full-record/WOS:000427500900004.[24] 严晓强, 胡泽勇, 孙根厚, 谢志鹏. 那曲高寒草地上四种地表通量计算方法的对比. 高原气象[J]. 2018, 37(2): 358-370, [25] 贾佳, 胡泽勇. 中国不同等级高温热浪的时空分布特征及趋势. 地球科学进展[J]. 2017, 32(5): 546-559, [26] Xie, Zhipeng, Hu, Zeyong, Gu, Lianglei, Sun, Genhou, Du, Yizhen, Yan, Xiaoqiang. Meteorological Forcing Datasets for Blowing Snow Modeling on the Tibetan Plateau: Evaluation and Intercomparison. JOURNAL OF HYDROMETEOROLOGY[J]. 2017, 18(10): 2761-2780, [27] Ma, Yaoming, Ma, Weiqiang, Zhong, Lei, Hu, Zeyong, Li, Maoshan, Zhu, Zhikun, Han, Cunbo, Wang, Binbin, Liu, Xin. Monitoring and Modeling the Tibetan Plateau's climate system and its impact on East Asia. SCIENTIFIC REPORTS[J]. 2017, 7: http://ir.itpcas.ac.cn/handle/131C11/8315.[28] Sun, Genhou, Hu, Zeyong, Sun, Fanglin, Wang, Jiemin, Xie, Zhipeng, Lin, Yun, Huang, Fangfang. An analysis on the influence of spatial scales on sensible heat fluxes in the north Tibetan Plateau based on Eddy covariance and large aperture scintillometer data. THEORETICAL AND APPLIED CLIMATOLOGY[J]. 2017, 129(3-4): 965-976, https://www.webofscience.com/wos/woscc/full-record/WOS:000406123400018.[29] 谢志鹏, 胡泽勇, 刘火霖, 孙根厚, 杨耀先, 蔺筠, 黄芳芳. 陆面模式CLM4. 5对青藏高原高寒草甸地表能量交换模拟性能的评估. 高原气象[J]. 2017, 36(1): 1-12, [30] Huang, Fangfang, Ma, Weiqiang, Wang, Binbin, Hu, Zeyong, Ma, Yaoming, Sun, Genhou, Xie, Zhipeng, Lin, Yun. Air Temperature Estimation with MODIS Data over the Northern Tibetan Plateau. ADVANCES IN ATMOSPHERIC SCIENCES[J]. 2017, 34(5): 650-662, http://ir.itpcas.ac.cn/handle/131C11/8254.[31] Gu, Lianglei, Hu, Zeyong, Yao, Jimin, Sun, Genhou. Actual and Reference Evapotranspiration in a Cornfield in the Zhangye Oasis, Northwestern China. WATER[J]. 2017, 9(7): https://doaj.org/article/619feb1cfad841b99e4b329e6c946fab.[32] 胡泽勇. 1980-2010成都灰霾的变化特征及其与气候要素的关联性. 高原气象. 2017, [33] Sun, Genhou, Hu, Zeyong, Wang, Jiemin, Xie, Zhipeng, Lin, Yun, Huang, Fangfang. Upscaling analysis of aerodynamic roughness length based on in situ data at different spatial scales and remote sensing in north Tibetan Plateau. ATMOSPHERIC RESEARCH[J]. 2016, 176: 231-239, http://dx.doi.org/10.1016/j.atmosres.2016.02.025.[34] 刘火霖, 胡泽勇, 程思, 陈林. 基于Noah-LSM模式和CoLM模式的青藏高原中部陆面过程模拟. 冰川冻土[J]. 2016, 38(6): 1501-1509, [35] 白彬人, 胡泽勇. 高原热力作用对高原夏季风爆发的指示意义. 高原气象[J]. 2016, 35(2): 329-336, [36] 孙根厚, 胡泽勇, 王介民, 刘火霖, 谢志鹏, 蔺筠, 黄芳芳. 那曲地区两种空间尺度感热通量的对比分析. 高原气象[J]. 2016, 35(2): 285-296, [37] 蔺筠, 胡泽勇, 孙根厚, 谢志鹏, 黄芳芳. 城镇化发展背景下那曲地区气温变化的特征分析. 冰川冻土[J]. 2016, 38(3): 634-644, [38] 刘火霖, 胡泽勇, 杨耀先, 王愚, 孙根厚, 黄蓉. 青藏高原那曲地区冻融过程的数值模拟研究. 高原气象[J]. 2015, 34(3): 676-683, http://ir.kib.ac.cn/handle/151853/25919.[39] 荀学义, 胡泽勇, 崔桂凤, 王愚, 白彬人, 谷良雷. 青藏高原近地层及北侧气压系统的季节性振荡变化. 冰川冻土[J]. 2015, 37(2): 360-368, [40] Zhu Z K, Ma Y M, Li M S, Hu Z Y, Xu C, Zhang L, Han C B, Wang Y J, Ichiro T. Carbon dioxide exchange between an alpine steppe ecosystem and the atmosphere on the Nam Co area of the Tibetan Plateau (SCI). Agricultural and Forest Meteorology[J]. 2015, 203: 169-179, http://ir.casnw.net/handle/362004/27357.[41] 朱志鹍, 马耀明, 胡泽勇, 李茂善, 孙方林. 青藏高原那曲高寒草甸生态系统CO_2净交换及其影响因子. 高原气象[J]. 2015, 34(5): 1217-1223, http://ir.itpcas.ac.cn/handle/131C11/7089.[42] 马耀明, 胡泽勇, 田立德, 张凡, 段安民, 阳坤, 张镱锂, 杨永平. 青藏高原气候系统变化及其对东亚区域的影响与机制研究进展. 地球科学进展. 2014, 29(2): 207-215, http://lib.cqvip.com/Qikan/Article/Detail?id=48828722.[43] 胡泽勇. 藏北高原野外站点气温资料的插补及其近期变化的初步分析. 高原气象. 2014, [44] 王愚, 胡泽勇, 荀学义, 徐丽娇, 薛鹏成. 藏北高原土壤热传导率参数化方案的优化和检验. 高原气象[J]. 2013, 32(3): 646-653, [45] Xun X Y, Hu Z Y, Ma Y M. The dynamic plateau monsoon index and its association with general circulation anomalies (SCI). Advances in Atmospheric Sciences[J]. 2012, 29(6): 1249-1263, http://ir.casnw.net/handle/362004/16210.[46] 徐丽娇, 胡泽勇, 李婧华. 那曲站与其相邻野外站气象要素的对比分析. 高原气象. 2012, 31(4): 935-941, http://lib.cqvip.com/Qikan/Article/Detail?id=43034799.[47] 孙俊, 胡泽勇, 陈学龙, 张敏, 何慧根, 张渝杰. 黑河中上游不同下垫面动量总体输送系数和地表粗糙度对比分析. 高原气象. 2012, 31(4): 920-926, http://lib.cqvip.com/Qikan/Article/Detail?id=43034797.[48] 荀学义, 胡泽勇, 吴学宏, 薛志华, 崔桂凤, 杨力, 王旭东. 三套位势高度再分析资料在青藏高原地区的对比分析. 高原气象. 2011, 30(6): 1444-1452, http://lib.cqvip.com/Qikan/Article/Detail?id=40289215.