王蕾

教授📍、博士生導師

wanglei_ias@fudan.edu.cn

• 研究興趣

天氣、氣候預報與可預報性；平流層動力學🎦；大尺度大氣環流；北極海冰變率與可預報性；氣候-化學耦合；氣候變率與極端事件；混沌動力學

• 教育背景

學士學位（1999年7月），大氣科學，北京大學

碩士學位（2002年7月），氣象學🫱🏻，北京大學

碩士學位（2004年8月），大氣物理🥄，多倫多大學

博士學位（2010年11月），大氣物理，多倫多大學

• 研究經歷

2011年 1月— 2013年8月🚒，博士後👩‍🦰🔮，約翰霍普金斯大學地球與行星科學系

2013年9月 — 2015年8月🧝🏼‍♀️6️⃣，博士後，哥倫比亞大學氣候與社會國際研究所

2015年8月 — 2017年11月💠🧟‍♂️，副研究員😂📲，哥倫比亞大學拉蒙特-多爾蒂地球觀測所

2017年12月 — 2022年11月🍄‍🟫，青年研究員👳🏿‍♂️，沐鸣2/大氣科學研究院

2017年12月 — 2023年6月，兼職副研究員⏮，哥倫比亞大學拉蒙特-多爾蒂地球觀測所

2022年12月 — 至今👕，教授，沐鸣2/大氣科學研究院

• 承擔課題

(1) 國家自然科學基金委員會, 面上項目, 42375055, 春季平流層過程對北半球夏季氣候的影響, 2024-01-01 至 2027-12-31,主持

(2) 國家科學技術部, 國家重點研發計劃全球變化及應對專項課題, 2020YFA0608802, 西太平洋多尺度海氣過程與 ENSO 變異和可預報性的 聯系, 2020-12 至 2025-11,主持

(3) XX部, XXXX項目, 次季節-季節可預報性, 2019-12 至 2022-12,主持

(4) 國家自然科學基金委員會, 面上項目, 41875047, 平流層環流在北極海冰對北半球冬季氣候影響中的作用, 2019-01-01 至 2022-12-31,主持

(5) 國家科學技術部, 國家重點研發計劃全球變化及應對專項課題, 2019YFA0607002, 北極快速變化對中緯度極端天氣形成的影響機製研究, 2019-11 至 2024-10, 參與

(6) 國家自然科學基金委員會, 重大研究計劃, 91837206, 青藏高原積雪年代際變率歸因與全球氣候效應研究, 2019-01-01 至 2022-12-31, 參與

• 教學經歷

2023年— 至今♦️，動力氣象學/大氣動力學基礎，本科

2020年— 至今，大氣與海洋科學的行業創新與創業，本科

2020年— 2023年，數值天氣預報，本科

2020年— 2022年，大氣科學模擬和預測研究進展，博士

2019年— 2020年🆔，大氣科學漫談👩🏻‍🦽🍛，本科

2019年— 至今⛵️，氣候變化科學🕵🏽‍♀️，碩士

2019年— 2021年，大氣科學專業英語🦸🏽‍♀️，碩士&博士

2018年— 至今，大氣科學理論研究進展🛢，博士

• 學術兼職

2023—至今Journal of Climate副編輯（associate editor）

2020—至今國際氣象學和大氣科學協會（IAMAS）中國委員會秘書長

2021—2024中國海洋研究委員會（SCOR）青年委員

2020—至今Advances in Atmospheric Sciences編輯（editor）

2011年—至今，期刊審稿人🦎🌰：Atmospheric Chemistry and Physics, Atmospheric and Oceanic Science Letters, Atmospheric Science Letters, Advances in Atmospheric Sciences, Climate Dynamics, Geophysical Research Letters, Journal of Climate, Journal of Geophysical Research Atmospheres, Journal of Geophysical Research Oceans, Journal of Hydrometeorology, Journal of Meteorological Research, Mathematical Problems in Engineering, NPJ Climate and Atmospheric Science, Ocean Dynamics, Proceedings of Royal Society A, Quarterly Journal of the Royal Meteorological Society, SCIENCE CHINA Earth Sciences, Scientific Reports, Theoretical and Applied Climatology, Weather and Climate Dynamics.

• 獲獎情況

2022年3月，Reviewer Award，Journal of Meteorological Research

2022年1月🧚🏽‍♂️，2021年度研究生教育貢獻獎，沐鸣2

2020年4月⬆️，Top Downloaded Paper 2018-2019𓀊👰🏿，學術論文Large Impacts, Past and Future, of Ozone‐Depleting Substances on Brewer‐Dobson Circulation Trends: A Multimodel Assessment，Journal of Geophysical Research: Atmospheres

2018年4月👱‍♂️，學術論文The impact of ozone depleting substances on tropical upwelling, as revealed by the absence of lower stratospheric cooling since the late 1990s😛，高被引用論文（Highly Cited Paper），基本科學指標數據庫（ESI）

2017年2月🤟🥏，學術論文A robust empirical seasonal prediction of winter NAO and surface climate，2017年度Scientific Reports地球科學百佳論文之一（Top 100 Scientific Reports Earth science papers in 2017），Nature Research

• 培育學生獲獎情況

2024年🔇，龐達（共同導師：方向輝副教授），“沐鸣2平台優秀畢業生”

2023年，孫婉瑩🤎，第七屆地球系統科學大會“優秀學生展板獎”

2022年🔆🌛，馬旋，博士後創新人才支持計劃（簡稱“博新計劃”）

2019年🧵，馬旋🦃，國家獎學金

• 發表論文

（本人名稱加粗，通訊作者加*號，代表性論文）

 Dunstone, N., D. M. Smith, S. C. Hardiman, L. Hermanson, S. Ineson, G. Kay, C. F. Li, J. F. Lockwood, A. A. Scaife, H. Thornton, M. F. Ting, & L. Wang (2023). Skilful predictions of the summer north atlantic oscillation. Communications Earth & Environment, 4(1), 409.

 Wang, F., L. Wang*, T. Dai, and Y. Han, 2023: Interplay between Boreal Summer Intraseasonal Oscillation and Southern Hemisphere Stratospheric Polar Vortex Warming. Journal of Climate, 36(19), 6839-6853.

 Pang D., X. H. Fang*, and L. Wang, 2023: Importance of realistic zonal currents in depicting the evolution of tropical central Pacific sea surface temperature. Environ. Res. Lett., DOI 10.1088/1748-9326/ad0b21.

 Sun, W.Y., and L. Wang*, 2023: Diagnosing observed extratropical stationary wave changes in boreal winter. Environ. Res. Lett. 18 114014, DOI 10.1088/1748-9326/acfb99.

黃雯菁🦴，王蕾*. 2023. 北半球中高緯度阻塞對東亞寒潮影響過程中平流層和對流層的相互作用. 氣象學報，81（2）：1-17.

 Ma, X., and L. Wang*, 2023: The role of ozone depletion in the lack of cooling in the Antarctic upper stratosphere during austral winter. Advances in Atmospheric Sciences, 40(4), 619−633, doi:  10.1007/s00376-022-2047-9. Published: 08 February 2023

王林, 王蕾, 張洋. 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💂🏿：D0504大氣動力學. 大氣科學, 47(1): 125−131 doi: 10.3878/j.issn.1006-9895.2212.22304

 Ma, X., L. Wang*, D. Smith, L. Hermanson, R. Eade, N. Dunstone, S. C. Hardiman, and J. Zhang (2022). ENSO and QBO modulation of the relationship between Arctic sea ice loss and Eurasian winter climate. Environmental Research Letters, 2022, 17, 124016, DOI 10.1088/1748-9326/aca4e9

 Ma, X., F. Xie, X. Chen, L. Wang, Yang, G. Identifying a Leading Predictor of Arctic Stratospheric Ozone for April Precipitation in Eastern North America. Remote Sens. 2022, 14(19), 5040; https://doi.org/10.3390/rs14195040

 Wang F., R. Huang, L. Wang* (2022), Response of Tropical Convection over the Western Pacific to Stratospheric Polar Vortex during Boreal Winter. International Journal of Climatology, DOI:10.1002/joc.7869.

 Liu, S., Q. Wu*, Y. Yao, S. Schroeder, and L. Wang, (2022), Impacts of Autumn‐Winter Tibetan Plateau Snow Anomalies on North Atlantic‐Europe and Arctic Climate. Journal of Geophysical Research: Atmospheres, 127(12), e2021JD035791.

 Wang. L., and M. F. Ting, (2022), Stratosphere-Troposphere Coupling Leading to Extended Seasonal Predictability of Summer North Atlantic Oscillation and Boreal Climate, Geophysical Research Letters, DOI:10.1029/2021GL096362.

 Meng, L., J. Liu*, D. W. Tarasick, W. J. Randel*, A. K. Steiner, H. Wilhelmsen, L. Wang, & L. Haimberger, (2021), Continuous rise of the tropopause in the Northern Hemisphere over 1980-2020. Science advances, 7(45), eabi8065.

 Wang, F., and L. Wang* (2021), An exploration of the connection between quasi-biennial oscillation and Madden-Julian oscillation. Environ. Res. Lett., 16(11), 114021.

 Chen, R., G. Dai, R. Liu, and L. Wang* (2021), Seasonal Influence of the Atmosphere and Ocean on the fall Sea Ice Extent in the Barents–Kara Seas. J. Geophys. Res. Atmos., e2021JD035144.

 Dai, G., M. Mu*, C. Li, Z. Han, & L. Wang (2021). Evaluation of the Forecast Performance for Extreme Cold Events in East Asia With Subseasonal‐to‐Seasonal Data Sets From ECMWF. Journal of Geophysical Research: Atmospheres, 126(1), 2020JD033860.

 Dai, G., M. Mu*, & L. Wang (2021). The influence of sudden Arctic sea-ice thinning on North Atlantic oscillation events. Atmosphere-Ocean, 59(1), 39-52.

Wang. L., S. C. Hardiman, P. E. Bett, R. Comer, C. Kent, and A. A. Scaife (2020), What chance of a sudden stratospheric warming in the southern hemisphere? Environ. Res. Lett., 15, 104038

 Liu, S., Q. Wu*, S. R. Schroeder, Y. Yao, Y. Zhang, Wu, T., L. Wang & Hu, H. (2020). Near-global atmospheric responses to observed springtime Tibetan Plateau snow anomalies. Journal of Climate, 33(5), 1691-1706.

 Polvani, L.M., L. Wang*, M. Abalos, N. Butchart, M. Chipperfield, M. Deushi, S. Dhomse, P. Jöckel, D. Kinnison, M. Michou, O. Morgenstern, L. Oman, D. Plummer, and K. Stone (2019), Large impacts, past and future, of ozone depleting substances on Brewer-Dobson circulation trends: A multi-model assessment. J. Geophys. Res. Atmos., 124(13), 6669-6680. (*Corresponding author)

Wang. L., and A. W. Robertson, Subseasonal Predictability over the United States assessed from Two Operational Ensemble Prediction Systems. Climate Dynamics, 52(9-10), 5861-5875, doi:10.1007/s00382-018-4484-9.

Wang. L., X. J. Yuan, and C. Li, Subseasonal Forecast of Arctic Sea Ice Concentration via Statistical Approaches. Climate Dynamics, 52(7-8), 4953-4971, doi:10.1007/s00382-018-4426-6.

 Wang. L., M. F. Ting, and P. J. Kushner (2017), A robust empirical seasonal prediction of winter NAO and surface climate. Scientific Reports, doi:10.1038/s41598-017-00353-y. （Top 100 Scientific Reports Earth science papers in 2017）

 Polvani, L.M., L. Wang, D. W. Waugh, and V. Aquila (2017), The impact of ozone depleting substances on tropical upwelling, as revealed by the absence of lower stratospheric cooling since the late 1990s. Journal of Climate, DOI: 10.1175/JCLI-D-16-0532.1. （ESI Highly Cited Paper）

 Yuan, X., D. Chen, C. Li and L. Wang (2016), Arctic Sea Ice Seasonal Prediction by a Linear Markov Model. Journal of Climate, doi: 10.1175/JCLI-D-15-0858.1

Wang. L., X. J. Yuan, M. F. Ting, and C. Li (2016), Predicting Summer Arctic Sea Ice Concentration Intra-Seasonal Variability Using a Vector Auto-Regressive Model. Journal of Climate, 29 (4), 1529–1543.

Wang. L., M. Ting, D. Chapman, D. E. Lee, N. Henderson, and X. Yuan (2016), Prediction of northern summer low-frequency circulation using a high-order vector auto-regressive model. Climate Dynamics, 46 (3), 693-709, doi: 10.1007/s00382-015-2607-0.

Wang. L., and D. W. Waugh (2015), Seasonality in future tropical lower stratospheric temperature trends. J. Geophys. Res. Atmos., 120, 980–991, doi:10.1002/2014JD022090.

 Stolarski, R. S., D. W. Waugh, L. Wang, L. D. Oman, A. R. Douglass, and P. A. Newman (2014), Seasonal variation of ozone in the tropical lower stratosphere: Southern tropics are different from northern tropics. J. Geophys. Res. Atmos., 119, 6196–6206, doi:10.1002/2013JD021294.

Wang, L., P. J. Kushner, and D. W. Waugh (2013), Southern hemisphere stationary wave response to changes of ozone and GHGs. J. Climate, 26, 10205–10217, doi: 10.1175/JCLI-D-13-00160.1

 Garfinkel, C. I., D. W. Waugh, L. D. Oman, L. Wang and M. M. Hurwitz (2013), Temperature trends in the tropical upper troposphere and lower stratosphere: Connections with sea surface temperatures and implications for water vapor and ozone, J. Geophys. Res. Atmos., 118, 9658–9672, doi:10.1002/jgrd.50772.

Wang. L., and D. W. Waugh (2012), Chemistry-climate model simulations of recent trends in lower stratospheric temperatures and stratospheric residual circulation. J. Geophys. Res., 117, D09109, doi:10.1029/2011JD017130.

 Wang, L., and P. J. Kushner (2011), Diagnosing the stratosphere-troposphere stationary wave response to climate change in a general circulation model, J. Geophys. Res., 116, D16113, doi:10.1029/2010JD015473.

 Butchart, N., A. J. Charlton-Perez, I. Cionni, S. C. Hardiman, P. H. Haynes, K. Krüger, P. J. Kushner, P. A. Newman, S. M. Osprey, J. Perlwitz, M. Sigmond, L. Wang, H. Akiyoshi, J. Austin, S. Bekki, A. Baumgartner, P. Braesicke, C. Brühl, M. Chippereld, M. Dameris, S. Dhomse, V. Eyring, R. Garcia, H. Garny, P. Jöckel, J.-F. Lamarque, M. Marchand, M. Michou, O. Morgenstern, T. Nakamura, S. Pawson, D. Plummer, J. Pyle, E. Rozanov, J. Scinocca, T. G. Shepherd, K. Shibata, D. Smale, H. Teyssèdre, W. Tian, D. W. Waugh, and Y. Yamashita (2011), Multimodel climate and variability of the stratosphere. J. Geophys. Res., 116, D05102, doi:10.1029/2010JD014995.

 Wang, L., and P.J. Kushner (2010), Interpreting stationary wave nonlinearity in barotropic dynamics. J. Atmos. Sci., 67(7): 2240-2250. DOI: 10.1175/2010JAS3332.1.

王蕾, 康杜鵑, 李曉東 (2002), 多模態模型及其在氣候分析中的應用. 北京大學學報（自然科學版） 2002 Vol.38 (1): 83-89.

• 出版書籍

1👩🏻‍🚒，Butchart, N.*, A.J. Charlton-Perez, I. Cionni, S. C. Hardiman, K. Krüger, P. Kushner, P. Newman, S. M. Osprey, J. Perlwitz, F. Sassi, M. Sigmond, L. Wang (2010), Stratospheric dynamics, in SPARC CCMVal, SPARC CCMVal Report on the Evaluation of Chemistry-Climate Models, edited by V. Eyring, T. G. Shepherd, and D. W. Waugh, pp. 109–148, SPARC Rep. 5, World Meteorological Organization, Geneva, Switzerland.

#以上信息由本人提供，更新時間：2024/06/18