吴志伟(Zhiwei Wu)
吴志伟 二级教授/博士生导师 +86-21-31248866
研究领域为气候动力学,研究方向包括季风动力学,青藏高原气象学,中高纬-热带相互作用。主持完成国家自然科学基金重大研究计划之重点项目等国家级科研项目9项,获得多项省部级科技奖。在PNAS、Science Advance和科学通报等中外权威学术期刊共计发表论文100余篇,据Google Scholar统计:文章引用总计6000余次,个人H-指数37。2023和2024年连续被国际知名学术网站Research.com评为环境科学领域“中国最优秀科学家”。首次提出了春季NAO通过北大西洋“三极子”海温异常模态影响东亚夏季风变化的物理机制以及前者对后者季节预测的贡献,成果被NATURE评选为“科学亮点”(2009年,被引500余次)。揭示了青藏高原夏季积雪异常可通过激发独特的“南欧-东北亚”(SENA)型大气遥相关异常,进而影响欧亚热浪发生频数的机理,成果被Nature Climate Change评选为“科学亮点”(2015年)。首次定义了描述“旱涝急转”强度的定量指标并被水利部和中国气象局相关部门采纳投入业务使用(2006年)。回答了如何衡量东亚夏季风强度这一季风学界的基本科学问题,成果自被美国国家海洋大气管理局(NOAA)采纳,成为6个监测全球季风实况的指数之一(2008年起至今,被引600余次)。揭示了冬季青藏高原积雪可通过激发类似于“太平洋-北美”(PNA)型大气遥相关异常从而影响北美冬季天气气候,成果被NATURE以“Tibetan Plateau gets wired up for monsoon prediction”为题推介(2014年)。发现增强气候模式北极大尺度环流对不同大气变量以及地表辐射平衡作用的模拟能力,可显著提高北极海冰模拟的准确性,为北极和全球气候预测提供更可靠的模式基础,成果被NOAA评选为“科学亮点”(2021年)。
博士学位(2009年),气象学,夏威夷大学与中国科学院大气物理研究所联合培养 硕士学位(2006年),气象学,南京信息工程大学 学士学位(1993年),气象学,南京气象学院
2019年 — 至今,大气科学研究院副院长,复旦大学 2016年 — 至今,复旦特聘教授/博士生导师,复旦大学 2012年 — 2016年,教授/博士生导师,南京信息工程大学 2010年 — 2012年,NSERC Fellow,加拿大环境部 2009年 — 2010年,博士后,夏威夷大学
1. The University of Sydney – Fudan University Ignition Grants, “Predicting health risks related to abnormal Asian-Australian monsoon using causal AI technique”, 2024-07 至 2025-06,19万元,在研,主持 2. 科技部,国家重点研发计划,2023YFF0805100,气候系统年代际变化海-气关键过程、机理与预测,2023-12至 2028-11,1200万元,在研,参加 3. 国家自然科学基金委员会,重大研究计划之重点项目,92158203,西太平洋海洋性大陆多时间尺度热力异常及其与亚澳季风系统变异的联系,2022-01 至2025-12,266.7万元,在研,主持 4. 国家自然科学基金委员会,重大研究计划之总集成项目,91937302,青藏高原多圈层相互作用及其气候影响,2020-01 至2022-12,1200万元,在研,参加 5. 科技部,科技资源调查专项第二次青藏高原科技考察研究项目,2019QZKK0102,气候变化与西风—季风协同作用,2019-11至2024-10,2700万元,在研,参加 6. 国家自然科学基金委员会,重大项目,41790475,北极海-冰-气系统对欧亚大陆冬季极端天气事件可预报性的影响,2018-01至2022-12,2000万元,在研,参加 7. 国家自然科学基金委员会,重大研究计划之集成项目,91637312,青藏高原地-气耦合过程和海洋对区域能量和水分循环及全球气候的协同影响,2017-01至2019-12,400万元,已结题,参加 8. 科技部,国家重点研发计划,2016YFA0601801,全球变暖“停滞”现象辨识与机理研究,2016-07至 2021-06,1500万元,已结题,参加 9. 国家自然科学基金委员会,面上项目,41575075,mega-ENSO和北半球中高纬下垫面热力异常对东亚夏季风的协同影响机理,2016-01至 2019-12,88.4万元,已结题,主持 10. 科技部,“973”项目,2015CB453200,热带季节内振荡的触发机制及多尺度相互作用,2015-01至2019-12,1500万元,已结题,参加 11. 国家自然科学基金委员会,重大研究计划之重点项目,91437216,青藏高原多尺度热力异常对我国灾害性天气与旱涝的影响,2015-01至2018-12,340万元,已结题,主持 12. 江苏省人民政府,江苏省特聘教授(重点资助),季风动力学研究,2012-12至2015-11,200万元,已结题,主持 13. 国家自然科学基金委员会,青年基金项目,40605022,正常季风年华南夏季旱涝并存、旱涝急转及发生机制,2007-01至2009-12,27万元,已结题,主持
2018年9月 — 至今,大气科学理论研究进展,博士研究生,复旦大学大气与海洋科学系 2019年2月 — 至今,海气相互作用,博士研究生,复旦大学大气与海洋科学系 2019年9月 — 至今,大气科学导论,本科生,复旦大学大气与海洋科学系 2019年2月 — 至今,大气科学漫谈,本科生,复旦大学大气与海洋科学系
2024年— 至今,复旦大学教学指导委员会委员 2019年— 至今,教育部高等学校海洋科学类专业教学指导委员会委员 2019年— 至今,《Atmosphere-Ocean》,编委 2019年— 至今,《Atmosphere》,编委 2017年— 至今,《Journal of Meteorological Research》,编委 国家科技部,评审专家 国家自然科学基金委员会,评审专家 国家公派留学基金管理委员会,评审专家 2016年,极端气候的统计理论和变化规律及其未来预估,江苏省科学技术奖一等奖(排名第六) 2010年,东亚季风多尺度变率与我国旱涝机理研究,江苏省科学技术奖一等奖(排名第五) 2009年,区域气候变化诊断及其预测研究,江苏省科学技术进步奖二等奖(排名第七)
(本人名称加粗,通讯作者加*号) 2024 130. Zhou, T. and Zhiwei Wu* 2024: Asian-Australian monsoon as a mediator on North American surface air temperature anomalies. Atmos. Res., DOI: 10.1016/j.atmosres.2024.107427. 129. Cao, C. and Zhiwei Wu* 2024: Comparing MJO Intensity over the Tropical Western Pacific during Mega and Equatorial La Niña Winters. J. Climate, 37, 5309-5321. 128. Zhu, L., and Zhiwei Wu* 2024: Climatic influence of the Antarctic ozone hole on the East Asian winter precipitation. npj Climate Atmos. Sci., DOI: 101038/ s41612-024-00732-z. 127. Zhao, Y., Y. Liu, C. Yao, S. Li, Zhiwei Wu, and co-authors 2024: The Relationship between the South China Sea Summer Monsoon Onset and Pacific Meridional SST anomalies. Int. J. Climatol., DOI: 10.1002/joc.8534. 126. Jin, R., H. Yu, Zhiwei Wu, and co-authors 2024: Impact of extratropical circulation in East Asia on western North Pacific tropical cyclone frequency and intensity. J. Climate, 37, 2103-2117. 125. Zhang, P., B. Wang, Zhiwei Wu*, R. Jin, and C. Cao 2024: Intensified Gradient La Niña and Extra-tropical Thermal Patterns Drive the 2022 East and South Asian “Seesaw” Extremes. npj Climate Atmos. Sci., DOI: 10.1038/s41612-024-00597-2. 124. Wang, J., and Zhiwei Wu* 2024: Three types of east Asian summer rainfall associated with monsoon circulation and tropical cyclone activities: unique features and major influential factors. Climate Dyn., 62, 4099-4116. 123. Zhao, Y., Y. Tuo, Z. Yang, Zhiwei Wu, Z. Gong, and G. Feng 2024: Uncertainties of the South China Sea summer monsoon and its relationship with sea surface temperature from different reanalysis datasets. Int. J. Climatol., DOI: 10.1002/joc.8343. 122. Li, Y., and Zhiwei Wu* 2024: Regional patterns and trends of compound hot extremes in mainland China: A new objective approach. Environ. Res. Lett., DOI: 10.1088/1748-9326/ad178f. 121. Cao, C., and Zhiwei Wu* 2024: Distinct Changes in Boreal Summer Intraseasonal Oscillation over the Western North Pacific under Mega and Equatorial La Niña Conditions. Climate Dyn., 62, 4527-4537. 120. Zhong, W., and Zhiwei Wu* 2024: Forecasting East Asian winter temperature via subseasonal predictable mode analysis. Climate Dyn., 62, 277-297. 2023 119. Zhong, W., and Zhiwei Wu* 2023: Impact of stratospheric variability on subseasonal temperature reversals during late winter over the mid-high latitudes of East Asia. Atmos. Res., DOI: 10.1016/j.atmosres.2023.107115. 118. Zhu, L., and Zhiwei Wu* 2023: To what extent can the ozone valley over the Tibetan Plateau influence the East Asian summer precipitation? npj Climate Atmos. Sci., DOI: 101038/s41612-023-00508-x. 117. Gao, M., F. Wang, Y. Ding, Zhiwei Wu, and Co-authors, 2023: Large-scale climate patterns offer pre-seasonal hints on the co-occurrence of heat wave and O3 pollution in China. Proc. Natl. Acad. Sci. USA, 120(26), e2218274120, DOI: 10.1073/pnas.2218274120. 116. Zhang, P., and Zhiwei Wu* 2023: Insight into Asymmetry in the Impact of Different Types of ENSO on the NAO. Climate, 11, 136. (约稿) 115. Wang, J., and Zhiwei Wu* 2023: Distinctive Features of Monsoon-TC Joint Rainfall over Western North Pacific and its Relationship with the Maritime Continent Thermal Condition. Atmos.-Ocean, DOI: 10.1080/07055900.2023.2221217. 114. Zhong, W., Zhiwei Wu* 2023: Interannual variability of the wintertime Asian-Bering-North American teleconnection linked to Eurasian snow cover and Maritime Continent sea surface temperature. J. Climate, 36(9), 2815-2831. 113. Zha, P., and Zhiwei Wu* 2023: Contribution of the Tibetan Plateau Winter Snow Cover to Seasonal Prediction of the East Asian Summer Monsoon. Atmos.-Ocean, 61(1), 25-39. 112. Luo, R., Q. Ding, I. Baxter, X. Chen, Zhiwei Wu and co-authors 2023: Uncertain role of clouds in shaping summertime atmosphere-sea ice connections in reanalyses and CMIP6 models. Climate Dyn., DOI: 10.1007/s00382-023-06785-9. 2022 111. Shi, F., et al. 2022: Interdecadal to multidecadal variability of East Asian summer monsoon over the past half millennium. J. Geophys. Res., 127, e2022JD037260. 110. Zhong, W. and Zhiwei Wu* 2022: Subseasonal strength reversal of the East Asian winter monsoon. Climate Dyn., DOI: 10.1007/s00382-022-06610-9. 109. Zhang, P., Zhiwei Wu*, Z. Zhu and R. Jin 2022: Promoting seasonal prediction capability of the early autumn tropical cyclone formation frequency over the western North Pacific: effect of Arctic sea ice. Environ. Res. Lett., 17, 124012. 108. Zha, P., and Zhiwei Wu* 2022: Contribution of the Tibetan Plateau Snow Cover to the record-breaking rainfall over the Yangtze River Valley in June 2020. Atmos.-Ocean, DOI: 10.1080/07055900.2022.2151408. 107. Zhou, Y., R. Zhan, Y. Wang, Zhiwei Wu, G. Chen and L. Wang, 2022: Characteristics and Controlling Factors of Rapid Weakening of Tropical Cyclones After Reaching Their Intensity Peaks Over the Western North Pacific. J. Geophys. Res.,127, e2022JD036697, DOI:10.1029/2022JD036697. 106. Cao, C., and Zhiwei Wu* 2022: Modulation of the Tibetan Plateau snow cover on the interannual variations of the MJO-Related winter surface air temperature anomalies over East Asia. Climate Dyn., DOI: 10.1007/s00382-022-06275-4. 105. Jin, R., H. Yu, Zhiwei Wu, and P. Zhang 2022: Impact of the North Atlantic Sea Surface Temperature Tripole on the Northwestern Pacific Weak Tropical Cyclone Frequency. J. Climate, 35, 3057-3074. 104. Jin, R., H. Yu, M. Ying, and Zhiwei Wu 2022: An extreme tropical cyclone silence in the western North Pacific during July 2020. Atmos.-Ocean, DOI: 10.1080/07055900.2022.2060179. 103. Zhong, W. and Zhiwei Wu* 2022: Subseasonal variations of Eurasian wintertime surface air temperature: two distinct leading modes. Climate Dyn., DOI: 10.1007/s00382-021-06118-8. 2021 102. Zhong, S., H. Wang, X. Zhang, and Zhiwei Wu 2021: Rethinking the Characteristic Parameters of Typhoon Activity Frequency in the Western North Pacific. Atmos.-Ocean, DOI: 10.1080/07055900.2021.1990839. 101. Zhou, Y., J. Zhao, R. Zhan, P. Chen, Zhiwei Wu and L. Wang 2021: A Logistic-growth-equation-based Intensity Prediction Scheme for Western North Pacific Tropical Cyclones. Adv. Atmos. Sci., DOI: 10.1007/s00376-021-0435-1. 100. Zhang, P., and Zhiwei Wu* 2021: Reexamining the connection of El Niño and North American winter climate. Int. J. Climatol., DOI: 10.1002/joc.7204. 99. Fu, H., R. Zhan, Zhiwei Wu, Y. Wang and J. Zhao 2021: How Does the Arctic Sea Ice Affect the Interannual Variability of Tropical Cyclone Activity Over the Western North Pacific? Front. Earth Sci., DOI: 10.3389/feart.2021.675150. 98. Cao, C., F. Liu, Zhiwei Wu 2021: Role of cloud radiative feedback in the Madden–Julian oscillation dynamics: a trio-interaction model analysis. Theo. Appl. Climatol., DOI: 10.1007/s00704-021-03641-w. 97. Lyu, M., X. Jiang*, Zhiwei Wu*, Daehyun Kim and A. Adams 2021: Zonal-scale of the Madden-Julian Oscillation and its propagation speed on the interannual time-scale. Geophys. Res. Lett., DOI: 10.1029/2020GL091239. 96. Zhang, P., Zhiwei Wu* and R. Jin 2021: How can the winter North Atlantic Oscillation influence the early summer precipitation in Northeast Asia: effect of the Arctic sea ice. Climate Dyn., DOI: 10.1007/s00382-020-05570-2. 95. Luo, R., Q. Ding*, Zhiwei Wu*, I. Baxter, M. Bushuk, Y. Huang, and X. Dong 2021: Summertime atmosphere-sea ice coupling in the Arctic simulated by CMIP5/6 models: Importance of large-scale circulation. Climate Dyn., DOI: 10.1007/s00382-020-05543-5. (Highlighted by NOAA) 94. Ye, X. and Zhiwei Wu*, 2021: Seasonal Prediction of Arctic Summer Sea Ice Concentration from a Partial Least Squares Regression Model. Atmosphere, DOI: 10.3390/atmos12020230. 93. Chang, L., Zhiwei Wu* and J. Xu 2021: Contribution of the regional stratospheric warming to subseasonal prediction of the early winter haze pollution in the Sichuan Basin, China. Sci. Total Environ., 751, 1-11. 2020 92. 金蕊, 余晖, 吴志伟& 汤杰. 2020: 次季节-季节尺度热带气旋活动研究和预测技术进展. 大气科学学报[J], 43(1), 238-254. 91. You, Q., D. Chen, F. Wu, N. Pepin, Z. Cai, B. Ahrens, Z. Jiang, Zhiwei Wu, S. Kang, and A. AghaKouchak, 2020: Review of snow cover variation over the Tibetan Plateau and its influence on the broad climate system. Earth-Sci. Rev., DOI: 10.1016/j.earscirev.2020.103349. 90. Song, W., Y. Li and Zhiwei Wu 2020: Comparative analysis of cold events over central and eastern China associated with Arctic warming in Early 2008 and 2016. Atmos.Ocean, DOI: 10.1080/07055900.2020.1744510. 89. Chang, L., Zhiwei Wu* and J. Xu 2020: Potential impacts of the Southern Hemisphere polar vortices on central-eastern China haze pollution during boreal early winter. Climate Dyn., 55, 771-787. 88. Zhang, P., Zhiwei Wu*, J. Li and Z. Xiao 2020: Seasonal prediction of the northern and southern temperature modes of the East Asian winter monsoon: the importance of the Arctic sea ice. Climate Dyn., 54(7), 3583-3597. 87. Chang, L., Zhiwei Wu* and J. Xu 2020: A comparison of haze pollution variability in China using haze indices based on observations. Sci. Total Environ., DOI: 10.1016/j.scitotenv.2020.136929. 86. Dou, J., Zhiwei Wu* and J. Li 2020: The strengthened relationship between the Yangtze River Valley summer rainfall and the Southern Hemisphere annular mode in recent decades. Climate Dyn., 54(3), 1607-1624. 85. Lyu, M.,X. Jiang and Zhiwei Wu, 2019: A Cautionary Note on the Long-term Trend in Activity of the Madden-Julian Oscillation During the Past Decades. Geophys. Res. Lett., 46, 14063-14071. 84. You, Q.,T. Wu, L. Shen, N. Pepin, L. Zhang, Z. Jiang, Zhiwei Wu, S. Kang, and A. AghaKouchak, 2019: Review of snow cover variation over the Tibetan Plateau and its influence on the broad climate system. Earth-Sci. Rev., DOI: 10.1016/j.earscirev.2019.103043. 83. Gao, M.,P. Sherman, S. Song, Y. Yu, Zhiwei Wu and M. McElroy, 2019: Seasonal prediction of Indian wintertime aerosol pollution using the ocean memory effect. Sci. Adv., DOI: 10.1126/sciadv.aav4157. 82. Li, X., Zhiwei Wu* and Y. Li, 2019: A link of China warming hiatus with the winter sea ice loss in Barents–Kara Seas. Climate Dyn., 53, 2625-2642. 81. Luo, R., Zhiwei Wu*, P. Zhang and J. Dou 2019: Potential influence of the developing La Niña on the sea-ice reduction in the Barents-Kara Sea. Atmos. Ocean, 57(3), 182-194. 80. Lyu, M., Zhiwei Wu*, X. Shi and M. Wen, 2019: Distinct impacts of the MJO and the NAO on cold wave amplitude in China. Quart. J. Roy. Meteor. Soc., 145, 1617-1635. 79. Zhang, P., Zhiwei Wu* and J. Li, 2019: Reexamining the relationship of La Niña and the East Asian winter monsoon. Climate Dyn., 53(1), 779-791. 78. Ji Y., Y. J. Li and Zhiwei Wu, 2019: Boreal summer climatology and standard deviation in global low-frequency stream function fields at 200 hPa. J. Trop. Meteorol., 25(2), 153-161. 77. Zhang, P., B. Wang and Zhiwei Wu*, 2019: Weak El Niño and Winter Climate in the mid-high latitude Eurasia. J. Climate, 32, 402-421. 76. Wu, J. and Zhiwei Wu*, 2019: Interdecadal change of the spring NAO impact on the summer Pamir-Tienshan Snow Cover. Int. J. Climatol., 39, 629-642. 75. Li, J., R. Ding, Zhiwei Wu*, Q. Zhang, B. Li, and J. P. Li, 2019: Inter-decadal change in potential predictability of the East Asian summer monsoon. Theo. Appl. Climatol., 136, 403-415. 2018 74. Ye, X. and Zhiwei Wu*, 2018: Contrasting Impacts of ENSO on the Interannual Variations of Summer Runoff between the Upper and Mid-Lower Reaches of the Yangtze River. Atmosphere, 9(12), 478-492. 73. Lyu, M., M. Wen and Zhiwei Wu*, 2018: Possible contribution of the interannual Tibetan Plateau snow cover variation to the Madden-Julian Oscillation convection variability. Int. J. Climatol., 38, 3787-3800. 72. Ye, X. C. and Zhiwei Wu*, 2018: Seasonal prediction of the Yangtze River runoff using a partial-least square regression model. Atmos.-Ocean, 56, 117-128. 71. Dou, J. and Zhiwei Wu*, 2018: Southern Hemisphere origins for interannual variations of Tibetan Plateau snow cover in boreal summer. J. Climate, 31, 7701-7718. 70. Zhang, X. C., S. Zhong, Zhiwei Wu and Y. Li, 2018: Seasonal prediction of the typhoon genesis frequency over the Western North Pacific with a Poisson regression model. Climate Dyn., 51(11), 4585-4600. 69. Yu, L. L., Zhiwei Wu*, R. Zhang and X. Yang, 2018: Partial least regression approach to forecast the East Asian winter monsoon using Eurasian snow cover and sea surface temperature. Climate Dyn., 51(11), 4573-4584. 68. Jin, R., Zhiwei Wu* and P. Zhang, 2018: Tibetan Plateau Capacitor Effect during the Summer preceding ENSO: from the Yellow River climate perspective. Climate Dyn., 51(1), 57-71. 67. Yu, B., H. Lin, Zhiwei Wu and W. J. Merryfield, 2018: The Asian-Bering-North American teleconnection: Seasonality, maintenance, and climate impact on North America. Climate Dyn., 50, 2023-2038. 66. 王静, 祁莉, 吴志伟, 施晓晖 & 何金海. 2018: 多套土壤湿度替代资料在青藏高原的适用性分析. 高原气象[J], 37, 371-381. 65. 王静, 何金海, 祁莉, 吴志伟& 施晓晖. 2018: 青藏高原土壤湿度的变化特征及其对中国东部降水影响的研究进展. 大气科学学报[J], 41(1), 1-11. 64. 宋伟, 吴志伟& 李跃凤. 2018: 冬季中国东部与北极之间近地面温度变化的年际联系. 气候与环境研究[J], 23(4): 463-478. 2017 63. 李春晖, 吴志伟, 蒙伟光, 张艳霞& 谷德军. 2017: 影响华南后汛期季风持续性暴雨和热带气旋持续性暴雨的大尺度环流背景分析. 热带气象学报[J], 33(1), 11-20. 62. Zhang, J., Y. Jiang, H. Chen and Zhiwei Wu, 2017: Double-mode adjustment of Tibetan Plateau heating to the summer circumglobal teleconnection in the Northern Hemisphere. Int. J. Climatol., DOI: 10.1002/JOC.5201. 61. You, Q., Z. Jiang, L. Kong, Zhiwei Wu, Y. Tao, S. Kang, and N. Pepin, 2017: A comparison of heat wave climatologies and trends in China based on multiple definitions. Climate Dyn., 48, 3975-3989. 60. Zhang, P., Zhiwei Wu*, and H. Chen, 2017: Interdecadal Variability of the ENSO-North Pacific Atmospheric Circulation in Winter. Atmos. Ocean, 55(2), 110-120. 59. Qin, J., R. Ding, Zhiwei Wu*, J. Li and S. Zhao, 2017: Relationships between an extratropical ENSO precursor and leading modes of atmospheric variability in the Southern Hemisphere. Adv. Atmos. Sci., 34(3), 360-370. 58. Dou, J., Zhiwei Wu* and Y. Zhou, 2017: Potential impact of the May Southern Hemisphere annular mode on the Indian summer monsoon rainfall. Climate Dyn., 49, 1257-1269. 2016 57. Yu, B., H. Lin, Zhiwei Wu, and W. J. Merryfield, 2016: Relationship between North American winter temperature and large-scale atmospheric circulation anomalies and its decadal variation. Environ., Res. Lett., doi:10.1088/1748-9326/11/7/074001. 56. Zhou, Y., and Zhiwei Wu*, 2016: Possible impacts of mega-El Niño/Southern Oscillation and Atlantic multidecadal oscillation on Eurasian heat wave frequency variability. Quart. J. Roy. Meteor. Soc., 142, 1647-1661. 55. Zhang, L., Zhiwei Wu*, and Y. Zhou, 2016: Different impacts of typical and atypical ENSO on the Indian summer rainfall: ENSO-developing phase. Atmos.Ocean, 54, 440-456. 54. Wu, Zhiwei*, X. Li, Y. J. Li and Y. Li, 2016: Potential Influence of Arctic Sea Ice to the Inter-annual Variations of East Asian Spring Precipitation. J. Climate, 29, 2797-2813. 53. Wu, Zhiwei*, P. Zhang, H. Chen and Y. Li, 2016: Can the Tibetan Plateau Snow Cover influence the interannual variations of Eurasian Heat Wave Frequency? Climate Dyn., 46, 3405-3417. (Highlighted by Nature Climate Change) 52. Wu, Zhiwei*, and L. Yu, 2016: Seasonal Prediction of the East Asian Summer Monsoon with a Partial-least Square Model. Climate Dyn., 46, 3067-3078. 51. Chen, H., E. K. Schneider and Zhiwei Wu, 2016: Mechanisms of Internally Generated Multidecadal Variability in the Atlantic in a CGCM. Climate Dyn., 46, 1517-1546. 50. 王静, 祁莉, 何金海, & 吴志伟. 2016: 青藏高原春季土壤湿度与我国长江流域夏季降水的联系及其可能机理. 地球物理学报, 59(11), 3985-3995. 2015 49. Zhang, J., L. Li, Zhiwei Wu, and X. Li, 2015: Prolonged dry spells in recent decades over north-central China and their association with a northward shift in planetary waves. Int. J. Climatol., 35, 4829-4842. 48. Wu, Zhiwei*, and P. Zhang, 2015: Interdecadal Variability of the mega-ENSONAO Synchronization in Winter. Climate Dyn., 45, 1117-1128. 47. Wu, Zhiwei*, J. Dou and H. Lin, 2015: Potential Influence of the November-December Southern Hemisphere Annular Mode on the East Asian Winter Precipitation: A New Mechanism. Climate Dyn., 44, 1215-1226. 2014 46. Wu, Zhiwei, S. Chen, J. He and H. Chen, 2014: Quantifications of the Two “Flavors” of El Niño Using Upper-Ocean Heat Content. Atmos. Ocean, 52(4), 351-362. 45. Yim, S., B. Wang, J. Liu, and Zhiwei Wu, 2014: A comparison of regional monsoon variability using monsoon indices. Climate Dyn.,43(5), 1423-1437. 44. 马婷婷, 吴志伟*, 江志红, 解文璇, 2014: 4-6月MJO北传与东亚季风爆发的关系[J]. 热带气象学报, 30(5):921-931. 2013 43. Ma, T., Z. Jiang and Zhiwei Wu, 2013: Responses of the China Coldwave Intensity Principal Mode to a Warming Climate.Acta Meteorologica Sinica, 27(5), 673-683. 42. Zhong, S., Zhiwei Wu* and J. He, 2013: Comparisons of the Thermal Effects of the Tibetan Plateau with NCEP-I and ERA-40 Reanalysis Data. Atmos.Ocean, 51(1), 75-87. 41. Wu, Zhiwei*, H. Lin, Y. Li, and Y. Tang, 2013: Seasonal Prediction of Frost-killing Frequency in south-central Canada during the Cool/Overwintering-crop Growing Season. J. Appl. Meteor. Climatol., 52, 102-113. 40. 陈圣劼, 何金海, 吴志伟, 2013:一种新的El Niño 海气耦合指数[J]. 大气科学, 37(4):815-828. 2012 39. Wu, Zhiwei*, Z. Jiang, J. Li, S. Zhong and L. Wang, 2012: Possible Association of the western Tibetan Plateau Snow Cover with the Decadal to Interdecadal Variations of Northern China Heatwave Frequency. Climate Dyn., 39, 2393-2402. 38. Li, J, and Zhiwei Wu, 2012: Importance of autumn Arctic sea ice to northern winter snowfall.Proc. Natl. Acad. Sci. USA, 109(28), 1898, DOI: 10.1073/pnas.1205075109. 37. Ma, T., Zhiwei Wu* and Z. Jiang, 2012: How does coldwave frequency in China respond to a warming climate? Climate Dyn., 39, 24872496, DOI: 10.1007/s00382-012-1354-8. 36. Jiang, Z., T. Ma and Zhiwei Wu*, 2012: China Coldwave Duration in a Warming Winter: Change of the Leading Mode. Theo. Appl. Climatol., 110, 65-75. 35. Lin, H. and Zhiwei Wu, 2012: Indian Summer Monsoon Influence on the Climate in the North Atlantic-European Region. Climate Dyn., 39, 303-311. 34. Lin, H. and Zhiwei Wu, 2012: Contribution of Tibetan Plateau snow cover to the extreme winter conditions of 2009/10. Atmos. Ocean, 50(1), 86-94. 33. Wu, Zhiwei*, H. Lin, J. Li, Z. Jiang and T. Ma, 2012: Heat Wave Frequency Variability over North America: Two Distinct Leading Modes. J. Geophys. Res., 117, D02102, DOI: 10.1029/2011JD016908. 32. Wu, Zhiwei*, J. Li, Z. Jiang, and T. Ma, 2012: Modulation of the Tibetan Plateau Snow Cover on the ENSO Teleconnections: From the East Asian Summer Monsoon Perspective. J. Climate, 25, 2481-2489. 31. Wu, Zhiwei* and H. Lin, 2012: Interdecadal Variability of the ENSO-North Atlantic Oscillation Connection in boreal summer. Quart. J. Roy. Meteor. Soc., 138, 1668-1675. 30. Wu, Zhiwei*, J. Li, Z. Jiang, J. He and X. Zhu, 2012: Possible effects of the North Atlantic Oscillation on the strengthening relationship between the East Asian summer monsoon and ENSO. Int. J. Climatol., 32, 794-800. 2011 29. Wang, L., Q. Huang, A. Dai, Z. Guan, J. He, and Zhiwei Wu, 2011: Inhomogeneous distributions of Meiyu rainfall in the Jiang-Huai basin and associated circulation patterns. Climate Res., 50, 203-214. 28. Wu, Zhiwei*, H. Lin and T. Brien, 2011: Seasonal Prediction of Air Temperature associated with the Growing Season Start of Warm-season Crops across Canada. J. Appl. Meteor. Climatol., 50, 1637–1649. 27. Lin, H. and Zhiwei Wu, 2011: Contribution of the autumn Tibetan Plateau snow cover to seasonal prediction of North American winter temperature. J. Climate, 24, 2801-2813. 26. He, J., H. Lin and Zhiwei Wu, 2011: Another look at influences of the Madden-Julian Oscillation on the wintertime East Asian weather. J. Geophys. Res., 116, D03109, DOI 10.1029/2010JD014787. 25. Wu, Zhiwei, J. Li, Z. Jiang and J. He, 2011: Predictable climate dynamics of abnormal East Asian winter monsoon: once-in-a-century snowstorms in 2007/2008 winter. Climate Dyn., 37, 1661-1669. (ESI Top 1% Highly-cited Paper) 2010 24. Li, J., Zhiwei Wu, Z. Jiang and J. He, 2010: Can global warming strengthen the East Asian summer monsoon? J. Climate, 23, 6696-6705. 23. Wang, B., Zhiwei Wu, J. Liu, C.-P. Chang, J. Li and T.-J. Zhou, 2010: Another look at climate variations of the East Asian winter monsoon: Northern and southern temperature modes. J. Climate, 23, 1495-1512. 2009 22. Wu, Zhiwei, B. Wang, J. Li and F.-F. Jin, 2009: An empirical seasonal prediction model of the East Asian summer monsoon using ENSO and NAO. J. Geophys. Res.,114, D18120, DOI:10.1029/2009JD011733. (Highlighted by Nature, Vol. 461, 850) 21. Wu, Zhiwei, J. Li, B. Wang and X. Liu, 2009: Can the Southern Hemisphere annular mode affect China winter monsoon?J. Geophys. Res., 114,D11107, DOI:10.1029/2008JD011501. 20. Wu, Zhiwei, and J. Li, 2009: Seasonal prediction of the global precipitation annual modes with the Grid-point Atmospheric Model of IAP LASG (GAMIL). Acta Meteorologica Sinica,23(4), 428-437. 19. Wang, B., F. Huang, Zhiwei Wu, J. Yang, X. Fu, and K. Kikuchi, 2009: Multi-Scale Climate Variability of the South China Sea Monsoon: A Review. Dyn. Atmos. Oceans, DOI:10.1016/j.dynatmoce.2008.09.004, 47, 15-37. 18. Wang, B., J. Liu, J. Yang, T.-J. Zhou, and Zhiwei Wu, 2009: Distinct principal modes of early and late summer rainfall anomalies in East Asia. J. Climate,22, 3864-3875. 2008 17. Wu, Zhiwei, and J. Li, 2008: Prediction of the Asian-Australian monsoon interannual variations with the grid-point atmospheric model of IAP LASG (GAMIL). Adv. Atmos. Sci.,25(3), 387-394. 16. Wang, B., Zhiwei Wu, J. Li, J. Liu, C.-P. Chang, Y. Ding, G. Wu, 2008: How to measure the strength of the East Asian summer monsoon. J. Climate, 17, 4449-4462. (ESI Top 1% Highly-cited Paper) 15. Zhu, X., Zhiwei Wu, and J. H. He, 2008: Anomalous Meiyu onset averaged over the Yangtze River valley. Theo. Appl. Climatol.,94, 8195.DOI 10.1007/s00704-007-0347-8. 14. 竺夏英, 何金海和吴志伟*, 2008: 长江中下游入梅指数及早晚梅年的海气背景特征[J]. 大气科学, 32(1), 113-122. 2007 13. Zhu, X., J. He, and Zhiwei Wu, 2007: Meridional seesaw-like distribution of the Meiyu rainfall over the Changjiang-Huaihe River Valley and characteristics in the anomalous climate years. Science Bull.,52(17), 2420-2428. 12. He, J., Zhiwei Wu*, Z. Jiang and G. Han, 2007: “Climate effect” of the northeast cold vortex and its influences on Meiyu. Science Bull., 51(5), 671-679. 11. 吴志伟, 李建平, 何金海, 江志红和竺夏英, 2007: 正常季风年华南夏季“旱涝并存、旱涝急转”之气候统计特征[J]. 自然科学进展, 17(12), 1665-1671. 10. 竺夏英, 何金海和吴志伟, 2007: 江淮梅雨期降水经向非均匀分布及异常年特征分析[J]. 科学通报, 52(8), 951-957. 2006 9. Wu, Zhiwei, J. Li, J. He and Z. Jiang, 2006: Occurrence of droughts and floods during the normal monsoons in the mid- and lower reaches of the Yangtze River. Geophys. Res. Lett.,33, L05813, DOI:10.1029/2005GL024487. 8. Wu, Zhiwei, J. Li, J. He and Z. Jiang, 2006: Large-scale atmospheric singularities and summer long-cycle droughts-floods abrupt alternation in the middle and lower reaches of the Yangtze River. Science Bull., 51(16), 2027-2034. 7.吴志伟*, 何金海, 李建平和江志红, 2006: 长江中下游夏季旱涝并存及其异常年海气特征分析[J]. 大气科学, 30(4), 570-577. 6.吴志伟*, 江志红和何金海, 2006: 近50年华南前汛期降水、江淮梅雨和华北雨季旱涝特征对比分析[J]. 大气科学, 30(3), 391-401. 5. 苗春生, 吴志伟, 何金海和池艳珍, 2006: 近50年东北冷涡异常特征及其与前汛期华南降水的关系分析[J]. 大气科学, 30(6), 1249-1256. 4. 何金海, 吴志伟*, 江志红,苗春生和韩桂荣, 2006: 东北冷涡的"气候效应"及其对梅雨的影响[J]. 科学通报, 51(23), 2803-2809. 3. 吴志伟, 李建平, 何金海和江志红, 2006: 大尺度大气环流异常与长江中下游夏季长周期旱涝急转[J]. 科学通报, 51(14), 1717-1724. 2. 何金海, 吴志伟, 祁莉和姜爱军, 2006: 北半球环状模和东北冷涡与我国东北夏季降水关系分析[J]. 气象与环境学报, 22(1), 1-5. 1. 苗春生, 吴志伟和何金海, 2006: 北半球环状模(NAM)、东北冷涡与前汛期华南旱涝[J]. 热带气象学报, 22(6), 593-599.
1, Wu, Zhiwei, J. Li, 2016: Decadal to Interdecadal Variations of Northern China Heatwave Frequency: Impact of the Tibetan Plateau Snow Cover. In: Li, J., R. Swinbank, R. Grotjahn & H. Volkert (eds.), Dynamics and Predictability of Large-Scale, High-Impact Weather and Climate Events (Special Publications of the International Union of Geodesy and Geophysics). United Kingdom: Cambridge University Press, 370pp. 2, The World Climate Research Programme (Translated by Li J., Y. Liu, Z. Lin, Zhiwei Wu, L. Wang, X. Wang, X. Zhu, and W. Zheng), 2010: The World Climate Research Programme Achievements—Scientific Knowledge for Climate Adaptation, Mitigation and Risk Management. Beijing: China Meteorological Press, 84pp. 3, He, J.., Zhiwei Wu and Z. Wang (2008), Chapter 1: Climate of China and East Asian monsoon, in Regional climate studies of China, edited by C.-B. Fu et al., Springer-Verlag, Berlin, pp. 1-48.
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