2015.09~2019.07：云南大学、气象学、博士、导师：吴涧（教授）

2012.09~2015.07：云南大学、气象学、硕士、导师：吴涧（教授）

2008.09~2012.07：云南大学、大气科学、学士、导师：吴涧（教授）

2019.07~2021.12：中国科学院大气物理研究所，博士后，合作导师：符淙斌（院士）/赵得明（研究员）

2022.03~至今：云南大学，地球科学学院，副教授

主持项目

[1] 国家自然科学基金—面上项目：土地利用/覆盖变化的内外摩擦效应对中国近地面风速变化的影响（42475040），2025.01~202028.12，48.0万，在研

[2] 云南省优青项目：中国陆域近地面风速年代际变化的物理机制研究（202401AW070008），2024.03~2027.02，30.0万，在研

[3] 中国电建集团贵阳勘测设计研究院有限公司科技项目：基于人工智能和大数据的风功率密度预测模型研究（QG/GYY-A3-MST-04-2021/5），2023.06~2024.12，35.0万元，在研

[4] 国家自然科学基金—青年项目：中国陆域近地面风速多时间尺度变化的检测归因研究（42005023），2021.01~2023.12，24.0万，结题

[5] 中国科学院特别研究资助项目：我国陆域近地面风速未来时空演变特征及归因分析，2019.07~2021.12，80.0万，结题

[6] 中国博士后科学基金-面上项目：大尺度环流场改变影响我国陆域近地面风速的机理分析（2019M660761），2020.01~2021.12，8.0万，结题

参与项目

[7]   国家重点研发计划：“共享开放、自主可控的区域地球系统模式多元耦合及人类活动影响的反馈与预估”，第四课题：东亚气候-环境-生态系统的协同演变及未来人居环境预估（2023YFF0805504），2023.12~2028.11，558.0万元，在研，项目骨干，参与

[8]   国家自然科学基金—国际（地区）合作与交流项目：城市绿地缓解城市热岛效应：北京和华沙的比较研究（42361134582），150.0万，2024.01~2026.12，在研，项目骨干，参与

[9] 国家自然科学基金—联合基金：三峡水库的区域气候效应及其水文循环响应机制研究（U2240218），2022.01~2025.12，260.0万元，在研，项目骨干，参与

[10] 国家重点研发计划：高分辨率区域地球系统模式的研发及应用 第四课题：区域地球系统模式与数据服务平台建设（2018YFA0606004），2018.05~2023.05，679.0万，结题，参与

[1] Zha JL, Chuan T, Wu J^*,   Zhao DM, Luo M, Feng JM, Fan WX, Shen C, & Jiang HP (2024) Attribution of   terrestrial near-surface wind speed changes across China at a centennial   scale. Geophysical Research Letters, 51, e2024GL108241, https://doi.org/10.1029/2024GL108241.

[2] T Chuan, Zha JL^*, Wu J, Zhao DM, Fan WX,   Jiang HP, & Lyu YJ (2024) Non-Synchronization of the decadal transition   in winter near-surface wind speed across northern and southern China. Geophysical   Research Letters, 51, e2024GL110246, https://doi.org/10.1029/2024GL110246

[3] Zha JL, Chuan T, Qiu Y, Wu J^*,   Zhao DM, Fan WX, Lyu YJ, Jiang HP, Deng KQ, Andres-Martin M, &   Azorin-Molina C (2024) Projected near-surface wind speed and wind energy over   Central Asia using dynamical downscaling with bias-corrected global climate   models. Advances in Climate Change Research, 15,   669−679, https://doi.org/10.1016/j.accre.2024.07.007

[4] Li LW, Zha JL^*, Chuan T, Wu J, Zhao DM, Fan WX, Lyu YJ, & Jiang HP (2024)   Decadal changes and potential causes of near-surface wind speed in Northern   Hemisphere at centennial time scale. Advances in   Climate Change Research, https://doi.org/10.1016/j.accre.2024.10.002

[5] Zha JL, Shen C, Wu J, Zhao DM^*,   Fan WX, Jiang HP, & Zhao TB (2023) Evaluation and Projection of Changes   in Daily Maximum Wind Speed over China based on CMIP6. Journal of Climate,   36, 1503−1520, https://doi.org/10.1175/JCLI-D-22-0193.1

[6] Zha   JL, Shen C, Wu J, Zhao DM, Fan WX^*, Jiang HP,   Azorin-Molina C, & Chen DL (2022) Effects of Northern Hemisphere Annular   Mode on Terrestrial Near-Surface wind speed Changes over Eastern China from   1979 to 2017. Advances in Climate Change Research, 13, 875−883, https://doi.org/10.1016/j.accre.2022.10.005

[7] Zha JL, Shen C, Zhao DM^*,   Feng JM, Xu ZF, Wu J, Fan WX, Luo M, & Zhang LY (2022) Contributions of   external forcing and internal climate variability to changes in the summer   surface air temperature over East Asia. Journal of Climate, 36, 5013−5032, https://doi.org/10.1175/JCLI-D-21-0577.1

[8] Shen C, Zha JL^*, Wu J, Zhao DM,   Fan WX, & Azorin-Molina C (2022) Does   CRA-40 outperform other reanalysis products in evaluating near-surface wind   speed changes over land in China? Atmospheric Research, 266,   105948, https://doi.org/10.1016/j.atmosres.2021.105948

[9] Zha JL, Shen C, Wu J, Zhao DM*, Li ZB,   & Fan WX (2021) Projected Changes in Global Terrestrial Near-Surface Wind   Speed in 1.5-4.0 ℃ Global Warming Levels. Environmental Research Letters,   16, 114016, https://doi.org/10.1088/1748-9326/ac2fdd

[10] Zha JL, Shen C, Zhao DM, Wu J^*,   & Fan WX (2021) Slowdown and reversal of terrestrial near-surface wind   speed and its future changes over eastern China. Environmental Research   Letters, 16, 034028, https://doi.org/10.1088/1748-9326/abe2cd

[11] Zha JL, Zhao DM^*, Wu J, &   Shen C (2021) Terrestrial near-surface wind speed variations in China:   research progress and prospects. Journal of Meteorological Research,   35, 537−556, https://doi.org/10.1007/s13351-021-0143-x

[12] Shen C, Zha JL^*, Zhao DM, &   Wu J (2021) Centennial-scale variability in terrestrial near-surface wind   speed over China. Journal of Climate, 34, 5829−5846, https://doi.org/10.1175/JCLI-D-20-0436.s1

[13] Shen C, Zha   JL^*, Zhao DM, Wu J, Fan WX, Yang MX, & Li ZB (2021)   Estimating centennial-scale changes in global   terrestrial near-surface wind speed based on CMIP6. Environmental   Research Letters, 16, 084039, https://doi.org/10.1088/1748-9326/ac1378

[14] Zha JL, Wu J^*, Zhao DM, &   Fan WX (2020) Future projections of the near-surface wind speed over eastern   China based on CMIP5 datasets. Climate Dynamics, 54, 2361−2385, https://doi.org/10.1007/s00382-020-05118-4

[15] Zha JL, Zhao DM^*, &   Wu J (2019) Numerical simulation of the effects of land use and cover change   on the near-surface wind speed over Eastern China. Climate Dynamics,   53, 1783−1803, https://doi.org/10.1007/s00382-019-04737-w

[16] Zha JL, Wu J^*, & Zhao DM   (2019) A possible recovery of the near-surface wind speed in Eastern China   during winter after 2000 and the potential causes. Theoretical and   Applied Climatology, 136, 119−134, https://doi.org/10.1007/s00704-018-2471-z

[17] Zha JL, Wu J^*, & Zhao DM   (2017) Changes of the probabilities in different ranges of near-surface wind   speed in China during the period for 1970-2011. Journal of Wind   Engineering & Industrial Aerodynamics, 169, 156−167, https://doi.org/10.1016/j.jweia.2017.07.019

[18] Zha JL, Wu J^*, & Zhao DM   (2017) Effects of land use and cover change on the near-surface wind speed   over China in the last 30 years. Progress in Physical Geography-Earth and   Environment, 41, 46−67, https://doi.org/10.1177/0309133316663097

[19] Zha JL, Wu J^*, & Zhao DM   (2016) Changes of probabilities in different wind grades induced by land use   and cover change in Eastern China Plain during 1980-2011. Atmospheric   Science Letters, 17, 264−269,   https://doi.org/10.1002/asl.653

[20] Wu J^*, Zha JL, & Zhao DM   (2018) Changes in terrestrial near-surface wind speed and their possible   causes: an overview. Climate Dynamics, 51, 2039−2078, https://doi.org/10.1007/s00382-017-3997-y

[21] Wu J^*, Zha JL, & Zhao DM   (2018) Effects of surface friction and turbulent mixing on long-term changes   in the near-surface wind speed over the Eastern China Plain from 1981 to 2010.   Climate Dynamics, 51, 2285−2299, https://doi.org/10.1007/s00382-017-4012-3

[22] Wu J^*, Zha JL, & Zhao DM   (2018) Changes of wind speed at different heights over Eastern China during   1980-2011. International Journal of Climatology, 38, 4476−4495, https://doi.org/10.1002/joc.5681

[23] Wu J^*, Zha JL, & Zhao DM   (2017) Evaluating the effects of land use and cover change on the decrease of   surface wind speed over China in recent 30 years using a statistical   downscaling method. Climate Dynamics, 48, 131−149, https://doi.org/10.1007/s00382-016-3065-z

[24] Wu J^*,   Zha JL, & Zhao DM (2016) Estimating the impact of the   changes in land use and cover on the surface wind speed over the East China   Plain during the period 1980-2011. Climate Dynamics, 46, 847−863, https://doi.org/10.1007/s00382-015-2616-z

[25] Chuan   T, Wu J^*, Zha JL, Zhao DM, et al (2024)   Asynchronous changes in terrestrial near-surface wind speed among regions   across China from 1973 to 2017. Atmospheric Research, 300, 107220, https://doi.org/j.atmosres.2024.107220

[26] Liu   WL, Yang S, Chen DL, Zha JL, Zhang GF, Zhang ZT, Zhang TT,   Xu LL, Hu XM, and Deng KQ (2024) Rapid acceleration of Arctic near-surface   wind speed in a warming climate. Geophysical Research Letters, 51,   e2024GL109385, https://doi.org/10.1029/2024GL109385

[27] Deng KQ, Yang S, Liu WL, Li H, Chen DL, Lian T, Zhang GF, Zha   JL, & Shen C (2024) The offshore wind speed changes in China: an   insight into CMIP6 model simulation and future projections. Climate   Dynamics, 62, 3305−3319, https://doi.org/10.1007/s00382-023-07066-1

[28] Andres-Martin M, Azorin-Molina C, Shen C, Fernandez-Alvarez   J, Gimeno L, Vicente-Serrano S, & Zha JL (2023)   Uncertainty in surface wind speed projections over the Iberian Peninsula:   CMIP6 GCMs versus a WRF-RCM. Annals of the New York Academy of Sciences,   1529, 101−108, https://doi.org/10.1111/nyas.15063

[29] Shen C, Zha JL, Chen DL, et al (2022)   Evaluation of global terrestrial near-surface wind speed simulated by CMIP6   models and their future projections. Annuals of the New York   Academy of Sciences, 1518, 249−263, https://doi.org/10.1111/nyas.14910

[30] Wang J, Feng JM, Yan ZW, & Zha JL (2020)   Urbanization impact on regional wind stilling: A modeling study in the   Beijing-Tianjin-Hebei region of China. Journal of   Geophysical Research: Atmospheres, 125,   e2020JD033132, https://doi.org/10.1029/2020JD033132

[1] 查进林，孙欣雨，吕艳军，张浩，传婷，等（2024）一种基于多维注意力机制的复杂地形条件下风场重构方法. 发明专利，专利号：ZL   2024 1 0924192.9

[2] 查进林，陆雯茜，张浩，等(2024)   一种基于高分辨率风速模型的风速预测方法. 发明专利，申请号：2024101381451

[3] 张银量，查进林 (2023) 一种单轴对转型垂直轴风机. 发明专利，申请号：2023103134789

[4] 张鹏伟，张浩，查进林，等 (2023) 一种基于深度学习网络的智能识别算法. 发明专利，专利号：202311208058.0

[1] “云南省兴滇英才支持计划”—青年人才

[2]     宝钢教育奖/宝钢教育基金会

[3]     云南省优秀博士学位论文：《中国东部地区陆域近地面风速时空演变特征及机理分析》

[4]     云南省优秀硕士学位论文：《中国地区土地利用/覆盖变化影响近地面风速的分析》

本科生课程：《大气物理学》、《大气科学概论》

研究生课程：《高等大气动力学》