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人才详细信息

姓名:杨 威
性别:
学历:博士
专家类别:研究员
电话:010-84097049
传真:
电子邮箱:yangww@itpcas.ac.cn
职称:研究员
通讯地址:北京市朝阳区林萃路16号院3号楼

简介

个人简历

杨威,中国科学院青藏高原研究所研究员,博士生导师,中国科学院慕士塔格西风带环境综合观测研究站站长。2008年获中国科学院大学博士学位,2015年入选中国科学院青年创新促进会,2017年获得英国皇家学会 “牛顿高级学者基金”。2026年担任联合国教科文组织UNESCO冰冻圈科学行动十年计划高级专家。以第一和通讯作者在“The Cryosphere”,“Journal of Geophysical Research-Atmosphere”,“Climate Dynamics”,“Journal of Glaciology”等期刊发表论文三十余篇。近年来主持和参与了第二次青藏科考、中国科学院先导专项、国家自然科学基金重点/面上项目、中瑞国际合作等多项科研任务。

教育背景 

1998.09–2002.07,太原师范学院地理系,学士 

2002.09–2005.07,兰州大学资源环境学院,硕士 

2005.07–2008.07,中国科学院青藏高原研究所,博士 

工作经历 

2008.07–2011.11,中国科学院青藏高原研究所,助理研究员 

2011.11–2019.06,中国科学院青藏高原研究所,副研究员 

2012.03–2012.05,德国柏林理工大学,访问学者 

2019.06-今,中国科学院青藏高原研究所,研究员 

研究方向

现代冰川与高海拔气候变化、冰冻圈灾害

职务

社会任职

《冰川冻土》第九届编委会青年编委

《中国地质》第四届编委

中国气象学会冰冻圈与极地气象专业委员会委员

国际数字地球学会极地专业委员会委员

联合国教科文组织UNESCO冰冻圈科学行动十年计划高级专家

承担项目

  1. 国家自然科学基金“藏东南大型冰川的冷却效应研究”(2023-2026)课题负责人
  2. 拉萨市科技计划项目拉萨周边冰川脆弱性与保护方案研究 (2024-2026)课题负责人
  3. 西藏自治区科技术项目雅鲁藏布江大拐弯冰崩灾害监测预警研究2023-2025课题负责人
  4. 英国皇家学会牛顿高级学者基金: Understanding glaciers and hydrological changes in the Tibetan Plateau using high resolution monitoring and modelling(2017-2020)课题负责人
  5. 国家自然科学基金重大研究计划-培育项目“藏东南不同类型冰川消融机制及融水径流演变对比研究”(2016-2018), 课题负责人
  6. 国家自然科学基金“藏东南海洋性冰川物质平衡空间格局及其机制研究”(2014-2017)课题负责人
  7. 国家自然科学基金委员会与瑞士国家科学基金会合作研究项目青藏高原典型流域冰雪及融水径流对气候的响应研究(2020-2023),参与
  8. 国家自然科学基金重大研究计划-重点项目耦合多元示踪和水文模型的高寒流域径流水源解析研究 (2017-2020), 参与

获奖及荣誉

代表论著

代表论著

  1. Xie Y, Xu B, Zhu M, Fan Y, Wang P, Yang S, Zhao W, Yang W*. Glacier mass balance and its response to 2022 heatwaves for Kangxiwa Glacier in the eastern Pamir: insights from time-lapse photography. The Cryosphere. 2026, 20(4):2279-93.
  2. He Y, Dai Y, Lin C, He Z, Zhang T, Fan Y, Zhao C, Yang W*. Cooling effects of glaciers in the southeast Tibetan Plateau based on in situ observations and WRF‐LES simulation. Journal of Geophysical Research: Atmospheres. 2025, 130(16):e2025JD043526.
  3. Zhang T*, Yang W*, Wang Y, Zhao C, Long Q, Xiao C. Numerical modeling of ice detachment tipping processes: insights from the Sedongpu Glacier, southeastern Tibetan Plateau. The Cryosphere. 2025, 19(10):4487-98.
  4. He Z, Westoby M, Ren S, Zhao C, He Y, Zhang T, Yang W*. Quantifying the seasonal dynamics of a transitional ice cliff-pond system on a debris-covered glacier. Journal of Glaciology. 2025,71:e129.
  5. Ren S, Yao T, Yang W*, Miles ES, Zhao H, Zhu M, Li S. Changes in glacier surface temperature across the Third Pole from 2000 to 2021. Remote Sensing of Environment. 2024, 305:114076.
  6. Zhu F, Zhu M*, Yang W*, Wang Z, Guo Y, Yao T. Drivers of the extreme early spring glacier melt of 2022 on the central Tibetan Plateau. Earth and Space Science. 2024, 11(6):e2023EA003297.
  7. Yang W*, Wang Z, An B, Chen Y, Zhao C, Li C, Wang Y, Wang W, Li J, Wu G, Bai L. Early warning system for ice collapses and river blockages in the Sedongpu Valley, southeastern Tibetan Plateau. Natural Hazards and Earth System Sciences. 2023, 23(9):3015-29.
  8. Yang W, Zhao H*, Xu B, Li J, Wang W, Wu G, Wang Z, Yao T. Brief communication: How deep is the snow on Mount Everest?. The Cryosphere. 2023,17(7):2625 [Research Highlights]
  9. He Z, Yang W*, Wang Y, Zhao C, Ren S, Li C. Dynamic Changes of a Thick Debris-Covered Glacier in the Southeastern Tibetan Plateau. Remote Sensing. 2023; 15(2):357. https://doi.org/10.3390/rs15020357
  10. Zhao, C., Yang, W*., Westoby, M., An, B., Wu, G., Wang, W., Wang, Z., Wang, Y., and Dunning, S.: Brief communication: A ~50 Mm3 ice-rock avalanche on 22 March 2021 in the Sedongpu valley, southeastern Tibetan Plateau, The Cryosphere. 2022, https://doi.org/10.5194/tc-2021-306
  11. Yang W*, Zhu ML, Guo XF, Zhao HB*. Air temperature variability in high-elevation glacierized regions: observations from six catchments on the Tibetan Plateau. Journal of Applied Meteorology and Climatology. 2022. DOI: 10.1175/JAMC-D-21-0122.1
  12. An B*, Wang W*, Yang W*, Wu G, Guo Y, Zhu H, Gao Y, Bai L, Zhang F, Zeng C. Process, mechanisms, and early warning of glacier collapse-induced river blocking disasters in the Yarlung Tsangpo Grand Canyon, southeastern Tibetan Plateau. Science of the Total Environment, 2022: 816, 151652.
  13. Yang W*, Zhao CX, Westoby M, Yao TD, Wang YJ, Pellicciotti F, Zhou JM, He Z, Miles E, 2020. Seasonal Dynamics of a temperate Tibetan glacier revealed by high-resolution UAV photogrammetry and in situ measurements. Remote Sensing, 2020, 12, 2389. doi:10.3390/rs12152389
  14. Li SH*, Yao TD, Yu WS, Yang W*, Zhu ML. Energy and mass balance characteristics of the Guliya ice cap in the West Kunlun Mountains, Tibetan Plateau. 2019, Cold Regions Science and Technology,159:71-85
  15. Yang W*, Yao TD, Zhu ML, Wang YJ. Comparison of the meteorology and surface energy fluxes of debris-free and debris-covered glaciers in the southeastern Tibetan Plateau. Journal of Glaciology, 2017, DOI: 10.1017/jog.2017.77
  16. Yang W*, Guo XF, Wang YJ. Observational evidence of the combined influence of atmospheric circulations and local factors on near-surface meteorology in Dogze Co basin, inner Tibetan Plateau. International Journal of Climatology, 2017DOI: 10.1002/joc.5316
  17. Zhao HB, Yang W*, Yao TD, Tian LD, Xu BQ. Dramatic mass loss in extreme high-elevation areas of a western Himalayan glacier: observations and modeling. Scientific Reports. 2016, DOI: 10.1038/srep30706.
  18. Yang W*, Guo XF, Yao TD, Zhu ML, Wang YJ. Recent accelerating mass loss of southeast Tibetan glaciers and the relationship with changes in macroscale atmospheric circulations. Climate Dynamics. 2016, 47(3):805-815, DOI :10.1007/s00382-015-2872-y
  19. Zhu ML, Yao TD, Yang W*, Fabien M, Huintjes E, Li SH. Energy- and mass-balance comparison between Zhadang and Parlung No.4 glaciers on the Tibetan Plateau. Journal of Glaciology, 2015,61(227):595-607.  doi: 10.3189/2015JoG14J206.
  20. Yang W*, Yao TD, Guo XF, Zhu ML, Li SH, Kattel DB. Mass balance of a maritime glacier on the southeast Tibetan Plateau and its climatic sensitivity. Journal of Geophysical Research-Atmospheres, 2013, doi:10.1002/jgrd.50760.
  21. Yang W*, Guo XF, Yao TD, Yang K, Zhao L, Li SH, Zhu ML. Summertime surface energy budget and ablation modeling on a Tibetan maritime glacier. Journal of Geophysical Research-Atmospheres. 2011, doi:10.1029/2010JD015183
  22. Yang W*, Yao TD, Xu BQ, Zhou H. Influence of supraglacial debris on the summer ablation and mass balance in the 24K Glacier, southeastern Tibetan Plateau. Geografiska Annaler Series A-Physical Geography, 2010, 92: 353-360
  23. Yang W*, Yao TD, Xu BQ, Ma LL, Wang ZH, Wan M. Characteristics of recent temperate glacier fluctuations in the Parlung Zangbo River basin, southeast Tibetan Plateau. Chinese Science Bulletin, 2010, 55(20): 2097-2102
  24. Yang W*, Yao TD, Xu BQ, Wu GJ, Ma LL, Xin XD. Quick ice mass loss and abrupt retreat of the maritime glaciers in the Kangri Karpo Mountains, southeast Tibetan Plateau. Chinese Science Bulletin, 2008, 53(16):2547-2551
  25. Yao, T., Bolch, T., Chen, D., Gao, J., Immerzeel, W., Piao, S., Su, F., Thompson, L., Wada, Y., Wang, L., Wang, T., Wu, G., Xu, B., Yang, W., Zhang, G. and Zhao, P. (2022) The imbalance of the Asian water tower. Nature Reviews Earth & Environment.1-15.
  26. Jouberton, A., Shaw, T.E., Miles, E., McCarthy, M., Fugger, S., Ren, S., Dehecq, A., Yang, W. and Pellicciotti, F. (2022) Warming-induced monsoon precipitation phase change intensifies glacier mass loss in the southeastern Tibetan Plateau. Proceedings of the National Academy of Sciences 119(37), e2109796119.
  27. Yao TD, Thompson L, Yang W, Yu WS, Gao Y, Guo XJ, Yang XX, Duan KQ, Zhao HB, Xu BQ, Pu JC, Lu AX, Xiang Y, Kattel DB, Joswiak D. Different glacier status with atmospheric circulations in Tibetan Plateau and surroundings. Nature Climate Change. 2012, doi:10.1038/NCLIMATE1580.
  28. Bhattacharya A, Bolch T, Mukherjee K, King O, Menounos B, Kapitsa V, Neckel N, Yang W, Yao T. High Mountain Asian glacier response to climate revealed by multi-temporal satellite observations since the 1960s. Nature Communications2021; 12: 1-13.
  29. Xu, B., Cao, J., Hansen, J., Yao, T., Joswia, D.R., Wang, N., Wu, G., Wang, M., Zhao, H., Yang, W., Liu, X. and He, J. (2009) Black soot and the survival of Tibetan glaciers. Proceedings of the National Academy of Sciences of the United States of America 106(52), 22114-22118.
  30. Zemp M, Welty E, Nussbaumer SU, Bannwart J, Gärtner-Roer I, Wells A, Ahlstrøm AP, Anderson B, Andreassen LM, Azam MF, Barnett J…W Yang , B.Zagel. Global glacier mass change in 2025. Nature Reviews Earth & Environment, 2026, 7,213-215.
  31. . Global glacier mass change in 2025. Nature Reviews Earth & Environment. 2026 Apr 7.
  32. 张天诏, 杨威*, 赵传熙, 王忠彦, 何震, 王永杰, 邬光剑, 李久乐, 安宝晟. 青藏高原念青唐古拉山廓琼岗日1号冰川变化研究. 冰川冻土, 2024, 46(2): 379-391
  33. 赵传熙,杨威*,王永杰,丁宝弘,徐新常. 基于无人机技术的藏东南帕隆4号冰川表高程和运动速度变化研究. 北京师范大学学报。202056(14):557-565
  34. 赵传熙,杨威*,王永杰等. 冰川区不同气温估算方法评估 -以藏东南帕隆4号冰川为例. 冰川冻土,2019, 41(6): 1281-1291
  35. 邬光剑、杨威、王伟财、张国庆、周建民等(2023), 藏东南冰川快速退缩与冰湖灾害科学考察报告. 科学出版社
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