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https://www.researchgate.net/profile/Wen_Chen13

Web of Science Researcher ID: G-6058-2011

Scopus Author ID: 56183114900

 

研究兴趣

季风，气候动力学，平流层和对流层相互作用

 

教育背景

学士学位（1988年） 气象学  北京大学地球物理系

博士学位（1994年） 气象学  中国科学院大气物理研究所

 

研究经历

2022年–至今  特聘教授 云南大学

1999年–2022年  研究员 中国科学院大气物理研究所

1996年–1999年  副研究员 中国科学院大气物理研究所

2009年04月–2009年05月  访问教授 香港城市大学

2006年11月–2007年01月  访问教授 美国夏威夷大学

2002年04月–2002年10月  访问教授 日本东京大学

2000年04月–2000年07月  访问学者 德国马普气象研究所

1996年12月–1998年03月  博士后 德国马普气象研究所

1994年–1995年  助理研究员 中国科学院大气物理研究所

 

承担课题

2023.1–2027.12，国家自然科学基金重点项目（42230605），“全球变暖背景下中国夏季风北界年代际变化和机理及未来趋势预估”，主持，273万元

2018.1–2023.12，国家自然科学基金创新研究群体项目（41721004），“东亚季风变异特征与机理”，主持，1050万元

2020.1–2023.12，国家自然科学基金面上项目（41975051），“北半球冬季中高纬平流层环流异常下传和不下传事件特征的比较研究”，主持，62万元

2020.1–2022.12，国家自然科学基金委员会（NSFC）与泰国研究基金会（TRF）合作与交流项目（41961144016），“全球变暖背景下亚洲东南部地区夏季极端气候事件的年代际变异特征、机理和预测”，参加，200万元

2019.10–2022.9，NSFC与以色列科学基金会（ISF）合作研究项目（41961144025），“热带外地区气候对MJO和ENSO的响应机理及对次季节-季节尺度气候预测的新认识”，主持，175万元

2020.7–2022.6，NSFC与俄罗斯基础研究基金会（RFBR）合作与交流项目（42011530082），“东亚和西伯利亚地区的气候变异及其与平流层过程和热带长周期振荡的关系”，主持，15万元

2017.1–2019.12，NSFC与瑞典科研与教育国际合作基金会（STINT）合作交流项目（4161101356），“黄土高原植被变化对中国近两千年气候变化的影响”，主持，40万元

2017.9–2017.12，NSFC与泰国研究基金会（TRF）合作交流项目（41781240589），“第五届中泰气候变化研讨会”，主持，8万元

2016.9–2019.8，NSFC与泰国研究基金会（TRF）合作与交流项目（41661144018），“亚洲季风区不同陆地生态系统地气间碳、水通量交换特征及其对气候变率响应的机制研究”，参加，343万元

2016.7–2021.6，国家重点研发计划-全球变化及应对专项（2016YFA0600600），“全球变暖背景下热带关键区海气相互作用及其对东亚夏季风气候的影响研究”，主持，2500万元

2015.7–2015.12，NSFC与泰国研究基金会（TRF）合作交流项目（4151101212），“第四届中泰气候变化联合学术研讨会”，主持，15万元

2015.1–2019.12，NSFC与联合国环境规划署（UNEP）国际合作研究项目（41461144001），“全球变暖背景下东北亚多级生态过渡带地区的干湿及极端气候变化”，主持，300万元

2013.7–2013.12，NSFC与泰国研究基金会（TRF）合作交流项目（413111081），“第三届中泰气候变化联合学术研讨会”，主持，10万元

2013.4–2015.3，NSFC与英国皇家学会（RS）合作交流项目（41311130125），“通向季度预测的新认识”，主持，13万元

2013.1–2017.12，国家自然科学基金重点项目（41230527），“全球变暖背景下两类太平洋增温型对东亚冬、夏季风和台风活动的影响及其机理”，主持，292万元

2011.7–2011.12，NSFC与泰国研究基金会（TRF）合作交流项目（41110189）“第二届中泰气候变化联合学术研讨会”，主持，14万元

2011.1–2014.12，国家自然科学基金杰出青年科学基金项目（41025017），“东亚冬季风系统变异及其内动力学机理研究”，主持，200万元

2010.1–2011.12，NSFC与俄罗斯基础研究基金会（RFBR）合作交流项目（40910131），“平流层-对流层耦合及其与北半球海温异常的关系”，主持，9万元

2010.4–2012.12，NSFC与泰国研究基金会（TRF）合作交流项目（41010073），“与东亚冬季寒潮和夏季风爆发、中断相关联的东南亚季风变异特征研究”，主持，8万元

2010.1–2014.8，国家重点基础研究发展计划项目课题（2010CB428603），“平流层-对流层动力耦合过程与机理”，课题组长，312万元

2010.1–2012.12，国家自然科学基金海峡两岸合作与交流项目（40921160379），“全球变暖对西北太平洋台风活动和登陆我国台风的影响及其机理研究”，参加，200万元

2009.1–2009.12，NSFC与俄罗斯基础研究基金会（RFBR）合作交流项目（40810138），“平流层与对流层耦合以及中俄异常冬季气候的预测”，主持，8万元

2008.9–2011.12，国家科技支撑计划课题（2008BAK50B02），“重大气象水文致险因子的危险性综合评估技术”，参加，130万元

2008.1–2010.12，国家自然科学基金面上项目（40775035），“北半球平流层极涡变化规律及对东亚气候影响和机理研究”，主持，40万元

2008.1–2011.12，国家自然科学基金重点项目（40730952），“我国西北干旱区陆-气相互作用特征及其对气候影响机理”，参加，185万元

2007.5–2010.4，中国科学院知识创新工程重要方向项目（KZCX2-YW-220），“干旱、半干旱地带陆-气相互作用机理、模型设计及数值模拟研究”，主持，250万元

2007.1–2008.12，NSFC与俄罗斯基础研究基金会（RFBR）合作交流项目（40711120165），“平流层臭氧在欧亚大陆中高纬地区和东亚冬季异常天气和气候中的指示作用”，主持，9万元

2006.1–2008.12，国家自然科学基金面上项目（40575026），“北半球大气准定常行星波的年际年代际变化及其与东亚季风的关系研究”，参加，45万元

2005.1–2009.12，国家重点基础研究发展规划项目课题（2004CB418303），“引发我国南方频发性与持续性暴雨的气候背景研究”，课题组长，340万元

2004.1–2006.12，国家自然科学基金面上项目（40375021），“东亚冬季风年代际变化及其机理的研究”，主持，31万元

2003.1–2006.12，国家自然科学基金重点项目（40231005），“全球变化背景下华北持续干旱成因与预测理论研究”，参加，80万元

2002.11–2005.10，中国科学院知识创新工程重要方向项目（KZCX3-SW-218），“南水北调背景下华北地区水资源最优调配的理论研究”，课题组长，80万元。

2001.12–2004.12，中国科学院知识创新工程重要方向项目（ZKCX2-SW-210），“亚洲季风区海-陆-气相互作用对我国气候变化的影响”，课题组长，225万元

1998.10–2003.9，国家重点基础研究发展规划项目《我国重大气候和天气灾害的机理和预测理论的研究》（G1998040900），课题组长，559万元

1996.1–1998.12，国家自然科学基金青年科学基金项目（49505066），“中层大气中行星波输运作用的动力学研究”，主持，8万元

 

教学经历

2015年–2022年，气候动力学（研究生），中国科学院大学

2003年–2014年，高等大气动力学（研究生），中国科学院研究生院

1998年–2001年，高等大气动力学（研究生），中国科学院研究生院

1994年–1996年，高等大气动力学（研究生），中国科学院研究生院

 

学术兼职

2018年–2024年，WCRP（世界气候研究计划）-SPARC（平流层-对流层过程及其在气候中的作用）国际计划科学指导委员会（Scientific Steering Group）委员

2012年–2023年，第七、八、九届IAMAS中国委员会委员

2012年–2019年，第六、七届WCRP中国委员会委员

2007年–至今，中国气象学会动力气象学委员会主任委员

2023年–2028年，《The Innovation Geoscience》编委会委员（Editorial Board）

2022年–至今，《Journal of Tropical Meteorology》副主编（Associate Editors-in-chief）

2018年–至今，《中国科学：地球科学》《Science China Earth Sciences》编委(Associate Editor)

2013年–至今，《Frontiers in Earth Science》编委(Associate Editor)

2012年–至今，《气候与环境研究》常务编委

2012年–至今，《高原气象》编委

2011年–至今，《气象学报》常务编委

2011年–至今，《气象科学》编委

2001年–至今，《大气科学》常务编委

 

获奖情况

2022年，“东亚冬季风变化的新机制和气候影响”获中国气象局“十三五”以来气象科技优秀成果，入选爱思唯尔“2021年中国高被引学者”榜单以及“全球顶尖前10万科学家”榜单

2022年，获期刊《Journal of Meteorological Research》优秀审稿人奖（Reviewer Award）

2021年，《中国科学：地球科学》优秀编委，入选爱思唯尔“2020年中国高被引学者”榜单、斯坦福大学“2020全球前2%顶尖科学家榜单”以及路透社“气候变化研究领域全球最具影响力的1000位科学家”

2019年，获中国民主同盟北京市委员会授予优秀盟员称号

2018年，获中国科学院大学地球与行星科学学院“杰出贡献教师”奖和“杰出校友”

2016年，入选国家百千万人才工程，被授予“有突出贡献中青年专家”荣誉称号

2015年，获国务院政府特殊津贴和中国科学院朱李月华优秀教师奖

2013年，获中国科学院大学地球科学学院“杰出贡献教师”奖

2011年，获中国科学院“宝洁优秀研究生导师”奖

2010年，获教育部和国务院学位委员会全国优秀博士学位论文指导教师奖和大气物理研究所首届“中国科学院大气物理研究所优秀研究生指导教师奖”

2009年，获中国科学院“优秀研究生指导教师”奖和中国科学院研究生院教学贡献奖

2006年，获中国气象局和中国气象学会“中国气象青年科技人才奖”、中国气象学会第六届全国优秀青年气象科技工作者奖、中国科学院研究生院优秀教师奖励以及大气物理研究所首届“科技原始创新贡献奖”

2004年，获科技部国家重点基础研究发展计划（973计划）先进个人奖

1999年，获中国科学院青年科学家奖、中国科学院华为奖教金以及大气物理研究所“学笃风正”优秀中青年科技工作者奖

1996年，获第四届“赵九章优秀中青年科学工作奖”

 

发表论文（本人名称加粗，通讯作者加*号）

1.       An, X., W. Chen*, T. Ma, H. Aru, Q. Cai, C. Li, and L. Sheng*, 2023: Key role of Arctic sea-ice in subseasonal reversal of early and late winter PM_2.5 concentration anomalies over the North China Plain. Geophys. Res. Lett., 50, e2022GL101841. https://doi.org/10.1029/2022GL101841

2.       Chen, S., W. Chen, B. Yu, and R. Wu, 2023: How well can current climate models simulate the connection of the early spring Aleutian Low to the following winter ENSO? J. Climate, 36: 603-624

3.       Ma, T., and W. Chen*, 2023: Recent progress in understanding the interaction between ENSO and the East Asian winter monsoon: A review. Frontiers in Earth Science, 11: 1098517. doi: 10.3389/feart.2023.1098517

4.       Piao, J., W. Chen*, S. Chen, H. Gong, Z. Wang, and X. Lan, 2023: How well do CMIP6 models simulate the climatological northern boundary of the East Asian summer monsoon? Glob. Planet. Change, 221, 104034, https://doi.org/10.1016/j.gloplacha.2023.104034

5.       Wang, S., M. Ding, G. Liu, S. Zhao, W. Zhang, X. Li, W. Chen, C. Xiao, and D. Qin, 2023: New record of explosive warmings in East Antarctica. Science Bulletin, 68, 129-132

6.       Zheng, Y., S. Chen, W. Chen, and B. Yu, 2023: A continuing increase of the impact of the spring North Pacific Meridional Mode on the following winter El Niño and Southern Oscillation. J. Climate, 36: 585-602

7.       An, X., W. Chen*, P. Hu, S. Chen, and L. Sheng*, 2022: Intraseasonal variation of the northeast Asian anomalous anticyclone and its impacts on PM_2.5 pollution in the North China Plain in early winter. Atmos. Chem. Phys., 22, 6507-6521, https://doi.org/10.5194/acp-22-6507-2022

8.       An, X., W. Chen*, S. Fu, P. Hu, C. Li, and L. Sheng*, 2022: Possible dynamic mechanisms of high- and low-latitude wave trains over Eurasia and their impacts on air pollution over the North China Plain in early winter. J. Geophys. Res. Atmos., 127, e2022JD036732. https://doi.org/10.1029/2022JD036732

9.       An, X., L. Sheng, C. Li, W. Chen, Y. Tang, and J. Huangfu, 2022: Effect of rainfall-induced diabatic heating over southern China on the formation of wintertime haze on the North China Plain. Atmos. Chem. Phys., 22, 725-738, https://doi.org/10.5194/acp-22-725-2022

10.   Aru, H., S. Chen, and W. Chen*, 2022: Change in the variability in the Western Pacific pattern during boreal winter: roles of tropical Pacific sea surface temperature anomalies and North Pacific storm track activity. Clim. Dyn., 58, 2451-2468

11.   Cai, Q., W. Chen*, S. Chen, T. Ma, and C. I. Garfinkel, 2022: Influence of the Quasi-Biennial Oscillation on the spatial structure of winter-time Arctic Oscillation. J. Geophys. Res. Atmos., 127, e2021JD035564. https://doi.org/10.1029/2021JD035564

12.   Cai, Q., T. Ma*, W. Chen*, K. Wei, A. I. Pogoreltsev, and A. V. Koval, 2022: The observed connection between the Quasi-Biennial Oscillation and the persistence of the North Atlantic Oscillation in boreal winter. Int. J. Climatol., 42: 8777-8791

13.   Cen, S., W. Chen, S. Chen, L. Wang, Y. Liu, and J. Huangfu, 2022: Weakened influence of El Niño–Southern Oscillation on the zonal shift of the South Asian High after the early 1980s. Int. J. Climatol., 42: 7583-7597

14.   Chen, S., W. Chen*, B. Yu, and Z. Li, 2022: Impact of internal climate variability on the relationship between spring northern tropical Atlantic SST anomalies and succedent winter ENSO: the role of the North Pacific Oscillation. J. Climate, 35, 537-559

15.   Chen, S., and W. Chen*, 2022: Distinctive impact of spring AO on the succedent winter El Niño event: sensitivity to AO’s North Pacific component. Clim. Dyn., 58, 235-255

16.   Chen, S., W. Chen, J. Ying, Y. Zheng, and X. Lan, 2022: Interdecadal modulation of the Pacific Decadal Oscillation on the relationship between spring Arctic Oscillation and the following winter ENSO. Frontiers in Earth Science, 9: 810285

17.   Chen, W., P. Hu, and J. Huangfu, 2022: Multi-scale climate variations and mechanisms of the onset and withdrawal of the South China Sea summer monsoon. Science China Earth Sciences, 65(6): 1030-1046

陈文，胡鹏，皇甫静亮. 2022. 南海夏季风爆发和撤退的多时间尺度变化及其机制研究进展。中国科学：地球科学，52（6）：992-1009

18.   CHEN Zeyu, XU Jiyao, CHEN Hongbin, CHEN Wen, et al., 2022: Advances in the Researches of the Middle and Upper Atmosphere in China in 2020-2022. Chinese Journal of Space Science, 42(4): 684-711

19.   Choudhury, D., D. Nath, and W. Chen, 2022: Key features associated with the early and late South China summer monsoon onset. Theor. Appl. Climatol., 147, 99-108

20.   Choudhury, D., D. Nath, and W. Chen, 2022: Near-future Projection of Indian Summer Monsoon Circulation under 1.5 °C and 2.0 °C Warming. Atmosphere, 13, 1081

21.   Chwat, D., C. I. Garfinkel, W. Chen, and J. Rao, 2022: Which sudden stratospheric warming events are most predictable? Journal of Geophysical Research: Atmospheres, 127, e2022JD037521. https://doi.org/10.1029/2022JD037521

22.   Feng, J., and W. Chen, 2022: Respective and Combined Impacts of North Indian Ocean and Tropical North Atlantic SST Anomalies on the Subseasonal Evolution of Anomalous Western North Pacific Anticyclones. J. Climate, 35: 5623-5636

23.   Garfinkel, C. I., W. Chen, Y. Li, C. Schwartz, P. Yadav, and D. Domeisen, 2022: The winter North Pacific teleconnection in response to ENSO and the MJO in operational subseasonal forecasting models is too weak. J. Climate, 35: 4413-4430

24.   Gong, H., W. Zhang, L. Sun, Z. Dong, P. Zhang, L. Wang, W. Chen, and R. Wu, 2022: Evaluation of the Madden-Julian Oscillation in Fengyun-3B polar-orbiting satellite reprocessed OLR data. Journal of Meteorological Research, 36(6), 931-946

25.   Hu, P., W. Chen*, S. Chen, Y. Liu, L. Wang, and R. Huang, 2022: The leading mode and factors for coherent variations among the subsystems of tropical Asian summer monsoon onset. J. Climate, 35, 1597-1612

26.   Hu, P., W. Chen*, Z. Li, S. Chen, L. Wang, and Y. Liu, 2022: Close linkage of the South China Sea summer monsoon onset and extreme rainfall in May over Southeast Asia: role of the synoptic-scale systems. J. Climate, 35, 4347-4362

27.   Hu, P., W. Chen*, L. Wang, S. Chen, Y. Liu, and L. Chen, 2022: Revisiting the ENSO–monsoonal rainfall relationship: new insights based on an objective determination of the Asian summer monsoon duration. Environ. Res. Lett., 17, 104050, https://doi.org/10.1088/1748-9326/ac97ad

28.   Hu, P., W. Chen*, S. Chen, L. Wang, and Y. Liu, 2022: The weakening relationship between ENSO and the South China Sea summer monsoon onset in recent decades. Adv. Atmos. Sci., 39(3), 443-455

29.   Huangfu, J., W. Chen, X. Lai, D. Chen, and Z. He, 2022: Roles of synoptic-scale waves and intraseasonal oscillations in the onset of the South China Sea summer monsoon. Int. J. Climatol., 42: 2923-2934

30.   Huangfu, J., Y. Tang, L. Wang, W. Chen, R. Huang, and T. Ma, 2022: Joint influence of the quasi-biennial oscillation and Indian Ocean basin mode on tropical cyclone occurrence frequency over the western North Pacific. Clim. Dyn., 59, 3439-3449

31.   Huangfu, J., X. Cao, R. Wu, G. Chen and W. Chen, 2022: Influences of central Pacific warming on synoptic-scale wave intensity over the northwest Pacific. Clim. Dyn., 58, 555-567

32.   Liu, L., Z. Dong, H. Gong, L. Wang, W. Chen, and R. Wu, 2022: Climatology and trends of wintertime diurnal temperature range over East Asia in CMIP6 models: Evaluation and attribution. Atmospheric Research, 280, 106438, https://doi.org/10.1016/j.atmosres.2022.106438

33.   Ma, T., W. Chen*, S. Chen, C. I. Garfinkel, S. Ding, L. Song, Z. Li, Y. Tang, J. Huangfu, H. Gong, and W. Zhao, 2022: Different ENSO teleconnections over East Asia in early and late winter: role of precipitation anomalies in the tropical Indian Ocean–far western Pacific. J. Climate, 35: 4319-4335

34.   Ma, T., W. Chen*, H. Gong, P. Hu, Y. Jiao, X. An, and L. Wang, 2022: Linkage of Strong Intraseasonal Events of the East Asian Winter Monsoon to the Tropical Convections over the Western Pacific. Remote Sensing, 14, 2993. https://doi.org/10.3390/rs14132993

35.   Okoro, U. K., C. Usoh, C. Nwokocha, and W. Chen, 2022: Temperature range across Nigeria to the end of 21st century: prospects for photovoltaics based on CMIP5 and CORDEX perspectives. International Journal of Global Energy Issues, 44(1): 1-27

36.   Piao, J., W. Chen*, L. Wang, and S. Chen, 2022: Future projections of precipitation, surface temperatures and drought events over the monsoon transitional zone in China from bias-corrected CMIP6 models. Int. J. Climatol., 42:1203-1219

37.   Piao, J., W. Chen*, S. Chen, and H. Gong, 2022: Role of the internal atmospheric variability on the warming trends over Northeast Asia during 1970–2005. Theor. Appl. Climatol., 149, 1317-1328

38.   Sasikumar, K., D. Nath, X. Wang, W. Chen, and S. Yang, 2022: Recent enhancement and prolonged occurrence of MJO over the Indian Ocean and their impact on Indian summer monsoon rainfall. Clim. Dyn., 59, 2585-2598

39.   Schwartz, C., C. I. Garfinkel, P. Yadav, W. Chen, and D. Domeisen, 2022: Stationary wave biases and their effect on upward troposphere-stratosphere coupling in sub-seasonal prediction models. Weather and Climate Dynamics, 3, 679-692

40.   Song, L., S. Chen, W. Chen, J. Guo, C. Cheng, and Y. Wang, 2022: Distinct evolutions of haze pollution from winter to the following spring over the North China Plain: role of the North Atlantic sea surface temperature anomalies. Atmos. Chem. Phys., 22, 1669-1688, https://doi.org/10.5194/acp-22-1669-2022

41.   Tang, Y., J. Huangfu, R. Huang, and W. Chen, 2022: Simulation and Projection of Tropical Cyclone Activities over the Western North Pacific by CMIP6 HighResMIP. J. Climate, 35: 4171-4194

42.   Wang, L., G. Huang, W. Chen, T. Wang, C. Chotamonsak, and A. Limsakul, 2022: Decadal background for active extreme drought episode in the decade of 2010–2019 over southeastern mainland Asia. J. Climate, 35, 2785-2803

43.   Wang, L., W. Chen, Q. Fu, G. Huang, Q. Wang, C. Chotamonsak, and A. Limsakul, 2022: Super droughts over East Asia since 1960 under the impacts of global warming and decadal variability. Int. J. Climatol., 42: 4508-4521

44.   Wang, S., and W. Chen*, 2022: Impact of internal variability on recent opposite trends in wintertime temperature over the Barents–Kara Seas and central Eurasia. Clim. Dyn., 58, 2941-2956

45.   Wang, S., M. Ding, G. Liu, and W. Chen, 2022: Processes and mechanisms of persistent extreme rainfall events in the Antarctic Peninsula during austral summer. J. Climate, 35, 3643-3657

46.   Wang, S., M. Ding, G. Liu, T. Wei, W. Zhang, W. Chen, T. Dou, and C. Xiao, 2022: On the drivers of temperature extremes on the Antarctic Peninsula during austral summer. Clim. Dyn., 59, 2275-2291

47.   Xu, P., L. Wang, Z. Dong, Y. Li, X. Shen, and W. Chen, 2022: The British-Okhotsk Corridor Pattern and Its Linkage to the Silk Road Pattern. J. Climate, 35: 5787-5804

48.   Xu, Q., W. Chen, and L. Song, 2022: Two leading modes in the evolution of major sudden stratospheric warmings and their distinctive surface influence. Geophys. Res. Lett., 49, e2021GL095431. https://doi.org/10.1029/2021GL095431

49.   Xue, X., W. Chen, and S. Chen, 2022: Distinct impacts of two types of South Asian high on the connection of the summer rainfall over India and north China. Int. J. Climatol., 42: 8056-8072

50.   Yu, T., W. Chen*, P. Huang, J. Feng, and N. Jiang, 2022: Recent interdecadal changes in the Tropospheric Biennial Oscillation of the East Asian summer monsoon. Atmospheric Research, 277, 106301, https://doi.org/10.1016/j.atmosres.2022.106301

51.   Yu, T., J. Feng, W. Chen, K. Hu, and S. Chen, 2022: Enhanced tropospheric biennial oscillation of the East Asian summer monsoon since the late 1970s. J. Climate, 35, 1613-1628

52.   Yu, T., J. Feng, W. Chen, and S. Chen, 2022: The interdecadal change of the relationship between North Indian Ocean SST and tropical North Atlantic SST. J. Geophys. Res. Atmos., 127, e2022JD037078. https://doi.org/10.1029/2022JD037078

53.   Zhang, H., J. Huangfu, X. Wang, W. Chen, W. Peng, Q. Tang, Y. Chu, and Z. Xue, 2022: Comparative Analysis of Binhu and Cosmic-2 Radio Occultation Data. Remote Sensing, 14, 4958. https://doi.org/10.3390/rs14194958

54.   Aru, H., S. Chen, and W. Chen*, 2021: Comparisons of the different definitions of the western Pacific pattern and associated winter climate anomalies in Eurasia and North America. Int. J. Climatol., 41: 2840-2859

55.   Aru, H., W. Chen, and S. Chen, 2021: Is there any improvement in simulation of the wintertime Western Pacific teleconnection pattern and associated climate anomalies in CMIP6 compared to CMIP5 models? J. Climate, 34: 8841-8861

56.   Chen, S., B. Yu, R. Wu, W. Chen, and L. Song, 2021: The dominant North Pacific atmospheric circulation patterns and their relations to Pacific SSTs: historical simulations and future projections in the IPCC AR6 models. Clim. Dyn., 56, 701-725

57.   Chen, S., R. Wu, and W. Chen, 2021: Influence of North Atlantic sea surface temperature anomalies on springtime surface air temperature variation over Eurasia in CMIP5 models. Clim. Dyn., 57, 2669-2686

58.   Chen, S., R. Wu, W. Chen, L. Song, W. Cheng, and W. Shi, 2021: Weakened impact of autumn Arctic sea ice concentration change on the subsequent winter Siberian High variation around the late-1990s. Int. J. Climatol., 41(Suppl. 1):E2700-E2717

59.   Chen, S., W. Chen, R. Wu, B. Yu, and L. Song, 2021: Performance of the IPCC AR6 models in simulating the relation of the western North Pacific subtropical high to the spring northern tropical Atlantic SST. Int. J. Climatol., 41: 2189-2208

60.   Choudhury, D., D. Nath, and W. Chen, 2021: The modulation of Indian summer monsoon onset processes during ENSO through equatorward migration of the subtropical jet stream. Clim. Dyn., 57, 141-152

61.   Choudhury, D., Y. Tian, W. Chen, and Y. Gao, 2021: Influences of North Pacific anomalies on Indian summer monsoon onset. Q. J. R. Meteorol. Soc., 147, 3111-3123

62.   Ding, S., B. Wu, and W. Chen, 2021: Dominant characteristics of early autumn Arctic sea ice variability and its impact on winter Eurasian climate. J. Climate, 34, 1825-1846

63.   Feng, J., and W. Chen, 2021: Roles of the north Indian Ocean SST and tropical North Atlantic SST in the latitudinal extension of the anomalous western North Pacific anticyclone during the El Niño decaying summer. J. Climate, 34: 8503-8517

64.   Gong, H., L. Wang, W. Chen, and R. Wu, 2021: Evolution of the East Asian winter land temperature trends during 1961-2018: role of internal variability and external forcing. Environ. Res. Lett., 16, 024015, https://doi.org/10.1088/1748-9326/abd586.

65.   Hu, P., W. Chen*, S. Chen, Y. Liu, L. Wang, and R. Huang, 2021: Impact of the March Arctic Oscillation on the South China Sea summer monsoon onset. Int. J. Climatol., 41(Suppl. 1):E3239-E3248

66.   Huang, R., S. Chen, W. Chen, B. Yu, P. Hu, J. Ying, and Q. Wu, 2021: Northern poleward edge of regional Hadley cell over western Pacific during boreal winter: year-to-year variability, influence factors and associated winter climate anomalies. Clim. Dyn., 56, 3643-3664

67.   Huangfu, J., Y. Tang, T. Ma, W. Chen, and L. Wang, 2021: Influence of the QBO on tropical convection and its impact on tropical cyclone activity over the western North Pacific. Clim. Dyn., 57, 657-669

68.   Koval, A. V., W. Chen, K. A. Didenko, T. S. Ermakova, N. M. Gavrilov, A. I. Pogoreltsev, O. N. Toptunova, K. Wei, A. N. Yarusova, and A. S. Zarubin, 2021: Modelling the residual mean meridional circulation at different stages of sudden stratospheric warming events. Ann. Geophys., 39, 357-368

69.   Li, Z., W. Chen*, S. Chen, Y. Sun*, and D. Qian, 2021: Uncertainty of central China summer precipitation and related natural internal variability under global warming of 1°C to 3°C. Int. J. Climatol., 41: 6640-6653

70.   Li, Z., Y. Sun, T. Li, W. Chen, and Y. Ding, 2021: Projections of South Asian Summer Monsoon under Global Warming from 1.5° to 5°C. J. Climate, 34, 7913-7926

71.   Liu, L., W. Zhang, W. Chen*, R. Wu, and L. Wang, 2021: Evaluation of FY-3B reprocessed OLR data in the Asian-Australia monsoon region during 2011-2019: Comparison with NOAA OLR. Journal of Meteorological Research, 35(6), 964-974

72.   Liu, L., W. Chen, J. Guo, R. Wu, L. Wang, S. Wang, Y. Huo, and W. Tao, 2021: Large-scale pattern of the wintertime diurnal temperature range variations over North America during 1979-2018. Atmospheric Research, 257, 105614, https://doi.org/10.1016/j.atmosres.2021.105614

73.   Ma, T., and W. Chen*, 2021: Climate variability of the East Asian winter monsoon and associated extratropical-tropical interaction: a review. Annals of the New York Academy of Sciences, 1504: 44-62

74.   Ma, T., W. Chen*, J. Huangfu, L. Song, and Q. Cai, 2021: The observed influence of the Quasi-Biennial Oscillation in the lower equatorial stratosphere on the East Asian winter monsoon during early boreal winter. Int. J. Climatol., 41: 6254-6269

75.   Nath, D., K. Sasikumar, R. Nath, and W. Chen, 2021: Factors affecting COVID-19 outbreaks across the globe: role of extreme climate change. Sustainability, 13(6), 3029

76.   Piao, J., W. Chen*, S. Chen, H. Gong, and L. Wang, 2021: Mean states and future projections of precipitation over the monsoon transitional zone in China in CMIP5 and CMIP6 models. Climatic Change, 169: 35. https://doi.org/10.1007/s10584-021-03286-8

77.   Piao, J., W. Chen*, and S. Chen, 2021: Water vapor transport changes associated with the interdecadal decrease in the summer rainfall over Northeast Asia around the late-1990s. Int. J. Climatol., 41(Suppl. 1):E1469-E1482

78.   Piao, J., W. Chen*, and S. Chen, 2021: Sources of the internal variability-generated uncertainties in the projection of Northeast Asian summer precipitation. Clim. Dyn., 56, 1783-1797

79.   Song, L., S. Chen, W. Chen, W. Duan, and Y. Li, 2021: Interdecadal change in the relationship between boreal winter North Pacific Oscillation and Eastern Australian rainfall in the following autumn. Clim. Dyn., 57, 3265-3283

80.   Wang, L., L. Wang, W. Chen, and J. Huangfu, 2021: Modulation of winter precipitation associated with tropical cyclone of the western North Pacific by the stratospheric Quasi-Biennial oscillation. Environmental Research Letters, 16, 054004, https://doi.org/10.1088/1748-9326/abf3dd

81.   Wang, S., D. Debashis, and W. Chen, 2021: Nonstationary relationship between sea ice over Kara-Laptev seas during August-September and Ural blocking in the following winter. Int. J. Climatol., 41(Suppl. 1):E1608-E1622

82.   Wang, S., G. Liu, M. Ding, W. Chen, W. Zhang, and J. Lv, 2021: Potential mechanisms governing the variation in rain/snow frequency over the northern Antarctic Peninsula during austral summer. Atmospheric Research, 263, 105811, https://doi.org/10.1016/j.atmosres.2021.105811

83.   Wei, K., J. Ma, W. Chen, and P. Vargin, 2021: Longitudinal peculiarities of planetary waves-zonal flow interactions and their role in stratosphere-troposphere dynamical coupling. Clim. Dyn., 57, 28431-2862

84.   Xu, P., L. Wang, P. Huang, and W. Chen, 2021: Disentangling dynamical and thermodynamical contributions to the record-breaking heatwave over Central Europe in June 2019. Atmospheric Research, 252, 105446, doi: 10.1016/j.atmosres.105446

85.   Xu, P., L. Wang, G. K. Vallis, R. Geen, J. A. Screen, P. Wu, S. Ding, P. Huang, and W. Chen, 2021: Amplified waveguide teleconnections along the polar front jet favor summer temperature extremes over northern Eurasia. Geophys. Res. Lett., 48, e2021GL093735. doi:10.1029/2021GL093735

86.   Xue, X., W. Chen, S. Chen, S. Sun, and S. Hou, 2021: Distinct impacts of two types of South Asian highs on East Asian summer rainfall. Int. J. Climatol., 41(Suppl. 1):E2718-E2740

87.   Yu, T., W. Chen, J. Feng, K. Hu, L. Song, and P. Hu, 2021: Roles of ENSO in the link of the East Asian summer monsoon to the ensuing winter monsoon. J. Geophys. Res. Atmos., 126, e2020JD033994. https://doi.org/10.1029/2020JD033994

88.   Yu, T., J. Feng, W. Chen, and X. Wang, 2021: Persistence and breakdown of the western North Pacific anomalous anticyclone during the EP and CP El Niño decaying spring. Clim. Dyn., 57, 3529-3544

89.   Zhao, W., W. Chen*, S. Chen*, H. Gong, and T. Ma, 2021: Roles of anthropogenic forcings in the observed trend of decreasing late-summer precipitation over the East Asian transitional climate zone. Sci. Rep., 11: 4935, doi: 10.1038/s41598-021-84470-9

90.   Zhao, W., S. Chen, H. Zhang, J. Wang, W. Chen, R. Wu, W. Xing, Z. Wang, P. Hu, J. Piao, and T. Ma, 2021: Distinct impacts of ENSO on haze pollution in Beijing-Tianjin-Hebei region between early and late winters. J. Climate, 35, 687-704

91.   Zheng, Y., Chen, W.*, and Chen, S.*, 2021: Intermodel spread in the impact of the springtime Pacific meridional mode on following-winter ENSO tied to simulation of the ITCZ in CMIP5/CMIP6. Geophys. Res. Lett., 48, e2021GL093945. https://doi.org/10.1029/2021GL093945

92.   Zheng, Y., S. Chen*, W. Chen*, and B. Yu, 2021: Diverse influences of spring Arctic Oscillation on the following winter El Niño-Southern Oscillation in CMIP5 models. Clim. Dyn., 56, 275-297

93.   Zheng, Y., W. Chen, S. Chen, S. Yao, and C. Cheng, 2021: Asymmetric impact of the boreal spring Pacific Meridional Mode on the following winter El Niño-Southern Oscillation. Int. J. Climatol., 41: 3523-3538

94.   岑思弦，陈文*，胡鹏，薛旭. 2021. 南亚高压演变过程及其变异机制研究进展。高原气象，40（6）：1304-1317

95.   Cen, S., W. Chen*, S. Chen, Y. Liu, and T. Ma, 2020: Potential impact of atmospheric heating over East Europe on the zonal shift in the South Asian high: the role of the Silk Road teleconnection. Sci. Rep., 10: 6543, doi: 10.1038/s41598-020-63364-2

96.   Chen, S., W. Chen, R. Wu, and L. Song, 2020: Impacts of the Atlantic Multidecadal Oscillation on the relationship of the spring Arctic Oscillation and the following East Asian summer monsoon. J. Climate, 33(15): 6651-6672

97.   Chen, S., R. Wu, W. Chen, and K. Li, 2020: Why does a colder (warmer) winter tend to be followed by a warmer (cooler) summer over northeast Eurasia? J. Climate, 33: 7255-7274

98.   Chen, S., R. Wu, W. Chen, S. Yao, and B. Yu, 2020: Coherent interannual variations of springtime surface temperature and temperature extremes between central-northern Europe and Northeast Asia. J. Geophys. Res. Atmos., 125, e2019JD032226. https://doi.org/10.1029/2019JD032226

99.   Chen, S., R. Wu, W. Chen, K. Hu, and B. Yu, 2020: Structure and dynamics of a springtime atmospheric wave train over the North Atlantic and Eurasia. Clim. Dyn., 54, 5111-5126

100.  Chen, S., R. Wu, W. Chen, and B. Yu, 2020: Influence of winter Arctic sea ice concentration change on the El Niño-Southern Oscillation in the following winter. Clim. Dyn., 54, 741-757

101.  Chen, S., R. Wu, W. Chen, and B. Yu, 2020: Recent weakening of the linkage between the spring Arctic Oscillation and the following winter El Niño-Southern Oscillation. Clim. Dyn., 54, 53-67

102.  Chen, S., R. Wu, W. Chen, and L. Song, 2020: Projected changes in mid-high-latitude Eurasian climate during boreal spring in a 1.5 and 2℃ warmer world. Int. J. Climatol., 40: 1851-1863

103.  Chen, S., R. Wu, and W. Chen, 2020: Strengthened connection between springtime North Atlantic Oscillation and North Atlantic tripole SST pattern since the late-1980s. J. Climate, 33: 2007-2022

104.  Chen, S., W. Chen, R. Wu, B. Yu, and H.-F. Graf, 2020: Potential impact of preceding Aleutian Low variation on El Niño-Southern Oscillation during the following winter. J. Climate, 33: 3061-3077

105.  Chen, W., Q. Zhou, and X. Xue, 2020: Solar cycle modulation of the relationship between the boreal spring Northern Atlantic Oscillation and the East and Southeast Asian summer climate. Meteorology and Atmospheric Physics, 132, 287-295

106.  Chen Zeyu, Chen Hongbin, Xu Jiyao, Huang Kaiming, Xue Xianghui, Hu Dingzhu, Chen Wen, et al., 2020: Advances in the researches of the middle and upper atmosphere in China. Chinese Journal of Space Science, 40(5): 856-874

107.  Choudhury, D., D. Nath, and W. Chen, 2020: Atmospheric diabatic heating-induced wave train from the Caspian Sea to South and East Asia during the summer monsoon season. Atmospheric and Oceanic Science Letters, 13(5), 381-389

108.  Feng, J., W. Chen, and X. Wang, 2020: Reintensification of the anomalous western North Pacific anticyclone during the El Niño Modoki decaying summer: Relative importance of tropical Atlantic and Pacific SST anomalies. J. Climate, 33: 3271-3288

109.  Hu, P., W. Chen*, S. Chen, Y. Liu, L. Wang, and R. Huang, 2020: Impact of the September Silk Road pattern on the South China Sea summer monsoon withdrawal. Int. J. Climatol., 40: 6361-6368

110.  Hu, P., J. Huangfu*, W. Chen*, and R. Huang, 2020: South China Sea summer monsoon withdrawal and the synoptic-scale wave train over the western North Pacific. Int. J. Climatol., 40: 5599-5611

111.  Hu, P., W. Chen, S. Chen*, Y. Liu, and R. Huang, 2020: Extremely early summer monsoon onset in the South China Sea in 2019 following an El Niño event. Mon. Wea. Rev., 148(5), 1877-1890

112.  Hu, P., J. Huangfu*, W. Chen*, and R. Huang, 2020: Impacts of early/late South China Sea summer monsoon withdrawal on tropical cyclone genesis over the western North Pacific. Clim. Dyn., 55, 1507-1520

113.  Hu, P., W. Chen*, S. Chen, and R. Huang, 2020: Statistical analysis of the impacts of intra-seasonal oscillations on the South China Sea summer monsoon withdrawal. Int. J. Climatol., 40: 1919-1927

114.  Hu, P., W. Chen*, S. Chen, Y. Liu, R. Huang, and S. Dong, 2020: Relationship between the South China Sea summer monsoon withdrawal and September-October rainfall over southern China. Clim. Dyn., 54, 713-726

115.  Ma, J., W. Chen*, D. Nath, and X. Lan, 2020: Modulation by ENSO of the relationship between stratospheric sudden warming and the Madden–Julian oscillation. Geophys. Res. Lett., 47, e2020GL088894. doi:10.1029/2020GL088894

116.  Ma, T., W. Chen*, H.-F. Graf, S. Ding, P. Xu, L. Song, and X. Lan, 2020: Different Impacts of the East Asian Winter Monsoon on the Surface Air Temperature in North America during ENSO and Neutral ENSO years. J. Climate, 33: 10671-10690

117.  Nath, R., Y. Luo, and W. Chen, 2020: Future projection of summer surface air temperature trend over central India: Role of external forcing and internal variability. Int. J. Climatol., 40: 1107-1117

118.  Okoro, U. K., W. Chen, D. Nath, and H. C. Nnamchi, 2020: Variability and trends of atmospheric moisture in recent West African monsoon season and the Coordinated Regional Downscaling Experiment-Africa projected 21^st century scenarios. Int. J. Climatol., 40: 1149-1163

119.  Piao, J., W. Chen*, S. Chen, H. Gong, and Q. Zhang, 2020: Summer water vapor sources in Northeast Asia and East Siberia revealed by a moisture-tracing atmospheric model. J. Climate, 33: 3883-3899

120.  Piao, J., W. Chen*, S. Chen, H. Gong, X. Chen, and B. Liu, 2020: The intensified impact of El Niño on late-summer precipitation over East Asia since the early 1990s. Clim. Dyn., 54, 4793-4809

121.  Piao, J., W. Chen*, L. Wang, F. S. R. Pausata, and Q. Zhang, 2020: Northward extension of the East Asian summer monsoon during the mid-Holocene. Glob. Planet. Change, 184, 103046, doi: 10.1016/j.gloplacha.2019.103046

122.  Sasikumar, K., D. Nath, R. Nath, and W. Chen, 2020: Impact of extreme hot climate on COVID-19 outbreak in India. GeoHealth, 4, e2020GH000305. https://doi.org/10.1029/2020GH000305

123.  Tang, Y., J. Huangfu, R. Huang, and W. Chen, 2020: Surface warming reacceleration in offshore China and its interdecadal effects on the East Asia-Pacific climate. Sci. Rep., 10: 14811, doi: 10.1038/s41598-020-71862-6

124.  Wang, S., W. Chen*, S. Chen, and S. Ding, 2020: Interdecadal change in the North Atlantic storm track during boreal summer around the mid-2000s: role of the atmospheric internal processes. Clim. Dyn., 55, 1929-1944

125.  Wang, S., W. Chen*, S. Chen, D. Debashis, and L. Wang, 2020: Anomalous winter moisture transport associated with the recent surface warming over the Barents-Kara seas region since the mid-2000s. Int. J. Climatol., 40: 2497-2505

126.  Wang, S., D. Debashis, W. Chen, and T. Ma, 2020: CMIP5 model simulations of warm Arctic-cold Eurasia pattern in winter surface air temperature anomalies. Clim. Dyn., 54, 4499-4513

127.  Wang, S., D. Debashis, W. Chen, and L. Wang, 2020: Changes in winter stationary wave activity during weak mid-latitude and Arctic thermal contrast period. Int. J. Climatol., 40: 1755-1768

128.  Wei, K., W. Chen*, L. Xu, and C. Zhou, 2020: Stratosphere amplifies the global climate effect of wildfires. Science China Earth Sciences, 63: 309-311. 魏科，陈文*，徐路扬，周春江. 2020. 平流层放大火灾的全球气候影响。中国科学：地球科学，50（2）：318-320

129.  Xu, P., L. Wang, W. Chen, G. Chen, and I.-S. Kang, 2020: Intraseasonal variations of the British-Baikal Corridor pattern. J. Climate, 33: 2183-2200

130.  Xu, P., L. Wang, Y. Liu, W. Chen, and P. Huang, 2020: The record-breaking heat wave of June 2019 in Central Europe. Atmos. Sci. Let., 21:e964, doi: 10.1002/asl.964

131.  Xue, X., W. Chen, and Q. Zhou, 2020: Solar cycle modulation of the connection between boreal winter ENSO and following summer South Asian high. Journal of Atmospheric and Solar-Terrestrial Physics, 211, 105466, doi: 10.1016/j.jastp.2020.105466

132.  Xue, X., W. Chen, and S. Hou, 2020: The long-term variation in the South Asia High intensity measured by 150-hPa eddy geopotential height. Meteorology and Atmospheric Physics, 132, 833-844

133.  Yu, T., J. Feng, and W. Chen, 2020: Evaluation of CMIP5 models in simulating the respective impacts of East Asian winter monsoon and ENSO on the western North Pacific anomalous anticyclone. Int. J. Climatol., 40: 805-821

134.  Zhao, W., W. Chen, S. Chen, S. Yao, and D. Nath, 2020: Combined impact of tropical central-eastern Pacific and North Atlantic sea surface temperature on precipitation variation in monsoon transitional zone over China during August-September. Int. J. Climatol., 40: 1316-1327

135.  Zhao, W., W. Chen, S. Chen, D. Nath, and L. Wang, 2020: Interdecadal change in the impact of North Atlantic SST on August rainfall over the monsoon transitional belt in China around the late 1990s. Theor. Appl. Climatol., 140, 503-516

136.  Zhou, Q., and W. Chen, 2020: Unstable relationship between spring NAO and summer tropical cyclone genesis frequency over the western North Pacific. Acta Oceanologica Sinica, 39(5): 65-76

137.  陈剀，钟霖浩，华丽娟，陈文. 2020. 华西秋雨趋势变化的年代际转折及其成因分析. 气候与环境研究，25（1）：90-102

138.  马骥，陈文，兰晓青. 2020. 北半球冬季平流层强、弱极涡事件演变过程的对比分析. 大气科学，44（4）：726-747

139.  郑玉琼，陈文，陈尚锋. 2020. CMIP5模式对春季北极涛动影响后期ENSO不对称性的模拟能力分析. 大气科学，44（2）：435-454

140.  周群，陈文. 2020. 太阳活动11年周期与南极海冰的可能联系. 极地研究，32（3）：290-300

141.  周群，陈文. 2020. 太阳活动11年周期变化对南海夏季风爆发的可能影响. 热带气象学报，36（1）：25-31

142.  Chen, S., L. Song, and W. Chen, 2019: Interdecadal modulation of AMO on the winter North Pacific Oscillation-following winter ENSO relationship. Adv. Atmos. Sci., 36(12), 1393-1403

143.  Chen, S., R. Wu, and W. Chen, 2019: Projections of climate changes over mid-high latitudes of Eurasia during boreal spring: uncertainty due to internal variability. Clim. Dyn., 53, 6309-6327

144.  Chen, S., R. Wu, and W. Chen, 2019: Enhanced impact of Arctic sea ice change during boreal autumn on the following spring Arctic oscillation since the mid-1990s. Clim. Dyn., 53, 5607-5621

145.  Chen, S., R. Wu, W. Chen, and L. Song, 2019: Performance of the CMIP5 models in simulating the Arctic Oscillation during boreal spring. Clim. Dyn., 53, 2083-2101

146.  Chen, S., R. Wu, L. Song, and W. Chen, 2019: Interannual variability of surface air temperature over mid-high latitudes of Eurasia during boreal autumn. Clim. Dyn., 53, 1805-1821

147.  Chen, S., R. Wu, L. Song, and W. Chen, 2019: Present-day status and future projection of spring Eurasian surface air temperature in CMIP5 model simulations. Clim. Dyn., 52, 5431-5449

148.  Chen, W., L. Wang, J. Feng, Z. Wen, T. Ma, X. Yang, and C. Wang, 2019: Recent Progress in Studies of the Variabilities and Mechanisms of the East Asian Monsoon in a Changing Climate. Adv. Atmos. Sci., 36(9), 887-901

149.  Choudhury, D., D. Nath, and W. Chen, 2019: Impact of Indian Ocean warming on increasing trend in pre-monsoon rainfall and Hadley circulation over Bay of Bengal. Theor. Appl. Climatol., 137, 2595-2606

150.  Choudhury, D., D. Nath, and W. Chen, 2019: The role of surface air temperature over the east Asia on the early and late Indian Summer Monsoon Onset over Kerala. Sci. Rep., 9: 11756, doi: 10.1038/s41598-019-47945-4

151.  Ding, S., W. Chen*, H. F. Graf, Z. Chen, and T. Ma, 2019: Quasi-stationary extratropical wave trains associated with distinct tropical Pacific seasonal mean convection patterns: observational and AMIP model results. Clim. Dyn., 53, 2451-2476

152.  Ding, S., W. Chen*, H. F. Graf, and Y. Guo, 2019: Patterns of tropical Pacific convection anomalies and associated extratropical wave trains in AMIP5. Clim. Dyn., 52, 2565-2584

153.  Feng, J., W. Chen, H. Gong, J. Ying, and W. Jiang, 2019: An investigation of CMIP5 model biases in simulating the impacts of central Pacific El Niño on the East Asian summer monsoon. Clim. Dyn., 52, 2631-2646

154.  Gong, H., L. Wang, and W. Chen, 2019: Multidecadal changes in the influence of the Arctic Oscillation on the East Asian surface air temperature in boreal winter. Atmosphere, 10, 757, doi: 10.3390/atmos10120757

155.  Gong, H., L. Wang, and W. Chen, 2019: Recently strengthened influence of ENSO on the wintertime East Asian surface air temperature. Atmosphere, 10, 720, doi: 10.3390/atmos10110720

156.  Gong, H., L. Wang, W. Chen, and R. Wu, 2019: Time-varying contribution of internal dynamics to wintertime land temperature trends over the Northern Hemisphere. Geophys. Res. Lett., 46, 14674-14682, doi:10.1029/2019GL086220

157.  Gong, H., L. Wang, W. Chen, and R. Wu, 2019: Attribution of the East Asian winter temperature trends during 1979-2018: Role of external forcing and internal variability. Geophys. Res. Lett., 46, 10875-10882, doi:10.1029/2019GL084154

158.  Gong, H., L. Wang, W. Chen, R. Wu, W. Zhou, L. Liu, D. Nath, and X. Lan, 2019: Diversity of the wintertime Arctic Oscillation pattern among CMIP5 models: Role of stratospheric polar vortex. J. Climate, 32: 5235-5250

159.  Gong, H., W. Zhou, W. Chen, L. Wang, M. Y.-T. Leung, P. K.-Y. Cheung, and Y. Zhang, 2019: Modulation of the southern Indian Ocean dipole on the impact of El Niño-Southern Oscillation on Australian summer rainfall. Int. J. Climatol., 39: 2484-2490

160.  Hu, P., W. Chen*, and S. Chen, 2019: Interdecadal change in the South China Sea summer monsoon withdrawal around the mid-2000s. Clim. Dyn., 52, 6053-6064

161.  Hu, P., W. Chen*, S. Chen, and R. Huang, 2019: Interannual variability and triggers of the South China Sea summer monsoon withdrawal. Clim. Dyn., 53, 4355-4372

162.  Hu, P., W. Chen*, R. Huang, and D. Nath, 2019: Climatological characteristics of the synoptic changes accompanying South China Sea summer monsoon withdrawal. Int. J. Climatol., 39: 596-612

163.  Huang, J., W. Chen, Z. Wen, G. Zhang, Z. Li, Z. Zuo, and Q. Zhao, 2019: Review of Chinese atmospheric science research over the past 70 years: Climate and climate change. Science China Earth Sciences, 62(10): 1514-1550. 黄建平，陈文，温之平，张广俊，李肇新，左志燕，赵庆云. 2019. 新中国成立70年以来的中国大气科学研究：气候与气候变化篇。中国科学：地球科学，49（10），1607-1640

164.  Huang, R., S. Chen, W. Chen, P. Hu, and B. Yu, 2019: Recent strengthening of the regional Hadley circulation over the western Pacific during boreal spring. Adv. Atmos. Sci., 36(11), 1251-1264

165.  Huangfu, J., W. Chen, R. Huang, and J. Feng, 2019: Modulation of the impacts of the Indian Ocean basin mode on tropical cyclones over the Northwest Pacific during the boreal summer by La Niña Modoki. J. Climate, 32: 3313-3326

166.  Huangfu, J., W. Chen, M. Jian, and R. Huang, 2019: Impact of the cross-tropopause wind shear on tropical cyclone genesis over the Western North Pacific in May. Clim. Dyn., 52, 3845-3855

167.  Liu, L., J. Guo, W. Chen, R. Wu, L. Wang, H. Gong, B. Liu, D. Chen, and J. Li, 2019: Dominant interannual covariations of the East Asian–Australian land precipitation during boreal winter. J. Climate, 32: 3279-3296

168.  Liu, L., J. Guo, H. Gong, Z. Li, W. Chen, R. Wu, L. Wang, H. Xu, J. Li, D. Chen, and P. Zhai, 2019: Contrasting influence of Gobi and Taklimakan deserts on the dust aerosols in western North America. Geophys. Res. Lett., 46, 9064-9071, doi:10.1029/2019GL083508

169.  Okoro, U. K., W. Chen, and D. Nath, 2019: Recent variations in geopotential height associated with West African monsoon variability. Meteorology and Atmospheric Physics, 131, 553-565

170.  Wang, L., G. Huang, and W. Chen, 2019: Towards a theoretical understanding of multiscalar drought indices based on the relationship between precipitation and standardized precipitation index. Theoretical and Applied Climatology, 136, 1465-1473

171.  Wang, L., Y. Liu, Y. Zhang, W. Chen, and S. Chen, 2019: Time-varying structure of the wintertime Eurasian pattern: role of the North Atlantic sea surface temperature and atmospheric mean flow. Clim. Dyn., 52, 2467-2479

172.  Wang, L., L. Wang, Y. Liu, and W. Chen, 2019: The 2017-18 winter drought in North China and its causes. Atmosphere, 10, 60, doi: 10.3390/atmos10020060

173.  Wang, L., L. Wang, Y. Liu, W. Gu, P. Xu, and W. Chen, 2019: The Southwest China flood of July 2018 and its causes. Atmosphere, 10, 247, doi: 10.3390/atmos10050247.

174.  Wang, S., D. Nath, W. Chen, and L. Wang, 2019: Recent strengthening of Greenland blocking drives summertime surface warming over northern Canada and eastern Siberia. J. Climate, 32: 3263-3278

175.  Xu, L. Y., K. Wei, X. Wu, S. P. Smishlyaev, W. Chen, and V. Y. Galin, 2019: The effect of super volcanic eruptions on ozone depletion in a chemistry-climate model. Adv. Atmos. Sci., 36(8), 823-836

176.  Xu, P., L. Wang, and W. Chen, 2019: The British-Baikal Corridor: A teleconnection pattern along the summertime polar front jet over Eurasia. J. Climate, 32: 877-896

177.  Xu, P., L. Wang, W. Chen, J. Feng, and Y. Liu, 2019: Structural changes in the Pacific-Japan pattern in the late 1990s. J. Climate, 32: 607-621

178.  Xue, X., and W. Chen, 2019: Distinguishing interannual variations and possible impacted factors for the northern and southern mode of South Asia High. Clim. Dyn., 53, 4937-4959

179.  Yu, T., J. Feng, and W. Chen, 2019: Linear respective roles of El Niño-Southern Oscillation and East Asian winter monsoon in the formation of the western North Pacific anticyclone. Int. J. Climatol., 39: 3257-3270

180.  Zhao, W., S. Chen*, W. Chen*, S. Yao, D. Nath, and B. Yu, 2019: Interannual variations of the rainy season withdrawal of the monsoon transitional zone in China. Clim. Dyn., 53, 2031-2046

181.  Zhao, W., W. Chen, S. Chen, S. Yao, and D. Nath, 2019: Inter-annual variations of precipitation over the monsoon transitional zone in China during August-September: Role of sea surface temperature anomalies over the tropical Pacific and North Atlantic. Atmos. Sci. Let., 20:e872, doi: 10.1002/asl.872

182.  朱红霞，陈文，冯涛，王林. 2019. 冬季西伯利亚高压的主要年际变化模态及其对东亚气温的影响. 高原气象，38（4）：685-692

183.  Chen, S., W. Chen*, and B. Yu, 2018: Modulation of the relationship between spring AO and the subsequent winter ENSO by the preceding November AO. Sci. Rep., 8: 6943, doi: 10.1038/s41598-018-25303-0

184.  Chen, S., R. Wu, W. Chen, and S. Yao, 2018: Enhanced linkage between Eurasian winter and spring dominant modes of atmospheric interannual variability since the early-1990s. J. Climate, 31: 3575-3595

185.  Chen, S., R. Wu, and W. Chen, 2018: A strengthened impact of November Arctic oscillation on subsequent tropical Pacific sea surface temperature variation since the late-1970s. Clim. Dyn., 51, 511-529

186.  Chen, S., R. Wu, and W. Chen, 2018: Modulation of spring northern tropical Atlantic sea surface temperature on the El Niño-Southern Oscillation–East Asian summer monsoon connection. Int. J. Climatol., 38: 5020-5029

187.  Chen, S., R. Wu, L. Song, and W. Chen, 2018: Combined influence of the Arctic Oscillation and the Scandinavia pattern on spring surface air temperature variations over Eurasia. J. Geophys. Res. Atmos., 123, 9410-9429

188.  Chen, S., B. Yu, W. Chen, and R. Wu, 2018: A review of atmosphere-ocean forcings outside the tropical Pacific on the El Niño-Southern Oscillation occurrence. Atmosphere, 9, 439, doi: 10.3390/atmos9110439

189.  Chen Zeyu, Chen Hongbin, Xu Jiyao, Lv Daren, Zhang Shaodong, Xue Xianghui, Tian Wenshou, Liu Renqiang, Chen Wen, et al., 2018: Advances in the researches of the middle and upper atmosphere in China. Chinese Journal of Space Science, 38(5): 763-780

190.  Ding, S., W. Chen*, H. F. Graf, Y. Guo, and D. Nath, 2018: Distinct winter patterns of tropical Pacific convection anomaly and the associated extratropical wave trains in the Northern Hemisphere. Clim. Dyn., 51, 2003-2022

191.  Feng, J., W. Chen, and X. Wang, 2018: Asymmetric responses of the Philippine Sea anomalous anticyclone/cyclone to two types of El Niño-Southern Oscillation during the boreal winter. Atmos. Sci. Let., 19:e866, doi: 10.1002/asl.866

192.  Gong, H., L. Wang, W. Zhou, W. Chen*, R. Wu, L. Liu, D. Nath, and M. Y.-T. Leung, 2018: Revisiting the northern mode of East Asian winter monsoon variation and its response to global warming. J. Climate, 31: 9001-9014

193.  Gong, H., L. Wang, W. Chen, and D. Nath, 2018: Multidecadal fluctuation of the wintertime Arctic Oscillation pattern and its implication. J. Climate, 31: 5595-5608

194.  Gong, H., L. Wang, W. Chen, R. Wu, G. Huang, and D. Nath, 2018: Diversity of the Pacific-Japan pattern among CMIP5 models: Role of SST anomalies and atmospheric mean flow. J. Climate, 31: 6857-6877

195.  Hu, P., W. Chen*, R. Huang, and D. Nath, 2018: On the weakening relationship between the South China Sea summer monsoon onset and cross-equatorial flow after the late 1990’s. Int. J. Climatol., 38: 3202-3208

196.  Hu, P., W. Chen*, and R. Huang, 2018: Role of tropical intraseasonal oscillations in the South China Sea summer monsoon withdrawal in 2010. Atmos. Sci. Let., 19:e859, doi: 10.1002/asl.859

197.  Huang, R., S. Chen, W. Chen, and P. Hu, 2018: Interannual variability of regional Hadley circulation intensity over western Pacific during boreal winter and its climatic impact over Asia-Australia region. J. Geophys. Res. Atmos., 123, 344-366

198.  Huang, R., S. Chen, W. Chen, and P. Hu, 2018: Has the regional Hadley circulation over western Pacific during boreal winter been strengthening in recent decades? Atmospheric and Oceanic Science Letters, 11(6), 454-463

199.  Huangfu, J., W. Chen, T. Ma, and R. Huang, 2018: Influences of sea surface temperature in the tropical Pacific and Indian Oceans on tropical cyclone genesis over the western North Pacific in May. Clim. Dyn., 51, 1915-1926

200.  Huangfu, J., W. Chen, X. Wang, and R. Huang, 2018: The role of synoptic-scale waves in the onset of the South China Sea summer monsoon. Atmos. Sci. Let., 19:e858, doi: 10.1002/asl.858

201.  Huangfu, J., R. Huang, and W. Chen, 2018: Interdecadal variation of tropical cyclone genesis and its relationship to the convective activities over the central Pacific. Clim. Dyn., 50, 1439-1450

202.  Huangfu, J., R. Huang, W. Chen, and T. Feng, 2018: Causes of the active typhoon season in 2016 following a strong El Niño with a comparison to 1998. Int. J. Climatol., 38(Suppl.1): e1107-e1118

203.  Liu, L., J. Guo, W. Chen, R. Wu, L. Wang, H. Gong, W. Xue, and J. Li, 2018: Large-scale pattern of the diurnal temperature range changes over East Asia and Australia in boreal winter：A perspective of atmospheric circulation. J. Climate, 31: 2715-2728

204.  Ma, T., W. Chen*, D. Nath, H.-F. Graf, L. Wang, and J. Huangfu, 2018: East Asian winter monsoon impacts the ENSO-related teleconnections and North American seasonal air temperature prediction. Sci. Rep., 8: 6547, doi: 10.1038/s41598-018-24552-3

205.  Ma, T., W. Chen*, J. Feng, and R. Wu, 2018: Modulation effects of the East Asian winter monsoon on El Niño-related rainfall anomalies in southeastern China. Sci. Rep., 8: 14107, doi: 10.1038/s41598-018-32492-1

206.  Nath, R., Y. Luo, W. Chen, and X. Cui, 2018: On the contribution of internal variability and external forcing factors to the cooling trend over the Humid Subtropical Indo-Gangetic Plain in India. Sci. Rep., 8: 18047, doi: 10.1038/s41598-018-36311-5

207.  Piao, J., W. Chen*, Q. Zhang, and P. Hu, 2018: Comparison of moisture transport between Siberia and Northeast Asia on annual and interannual time scales. J. Climate, 31: 7645-7660

208.  Piao, J., W. Chen*, S. Chen, and K. Wei, 2018: Intensified impact of North Atlantic Oscillation in May on subsequent July Asian inland plateau precipitation since the late 1970s. Int. J. Climatol., 38: 2605-2612

209.  Wang, L., G. Huang, W. Chen, W. Zhou, and W. Wang, 2018: Wet-to-dry shift over Southwest China in 1994 tied to the warming of tropical warm pool. Clim. Dyn., 51, 3111-3123

210.  Wei, K., Z. Cai, W. Chen, and L. Xu, 2018: The effect of a well-resolved stratosphere on East Asian winter climate. Clim. Dyn., 51, 4015-4028

211.  Xue, X., W. Chen*, S. Chen, and J. Feng, 2018: PDO modulation of the ENSO impact on the summer South Asian high. Clim. Dyn., 50, 1393-1411

212.  陈文，丁硕毅，冯娟，陈尚锋，薛旭，周群. 2018. 不同类型ENSO对东亚季风的影响和机理研究进展. 大气科学，42（3）：640-655

213.  胡鹏, 陈文*. 2018. 南海夏季风爆发与前期东亚冬季风异常的关系以及ENSO的作用[J]. 气候与环境研究, 23（4）：401-412

214.  黄荣辉，陈文，魏科，王林，皇甫静亮. 2018. 平流层大气动力学及其与对流层大气相互作用的研究：进展与问题. 大气科学，42（3）：463-487

215.  Cai, Z., K. Wei, L. Xu, X. Lan, W. Chen, and D. Nath, 2017: The influences of the model configuration on the simulation of stratospheric northern-hemisphere polar vortex in the CMIP5 models. Advances in Meteorology, vol. 2017, Article ID 7326759, 15 pages, doi:10.1155/2017/7326759

216.  Chen, S., W. Chen*, and B. Yu, 2017: The influence of boreal spring Arctic Oscillation on the subsequent winter ENSO in CMIP5 models. Clim. Dyn., 48, 2949-2965

217.  Ding, S., W. Chen*, J. Feng, and H. F. Graf, 2017: Combined impacts of PDO and two types of La Niña on climate anomalies in Europe. J. Climate, 30, 3253-3278

218.  Feng, J., W. Chen, and Y. Li, 2017: Asymmetry of the winter extra-tropical teleconnections in the Northern Hemisphere associated with two types of ENSO. Clim. Dyn., 48, 2135-2151

219.  Gong, H., L. Wang, W. Chen, X. Chen, and D. Nath, 2017: Biases of the wintertime Arctic Oscillation in CMIP5 models. Environ. Res. Lett., 12(1), 014001, doi: 10.1088/1748-9326/12/1/014001

220.  Huangfu, J., R. Huang, W. Chen, T. Feng, and L. Wu, 2017: Interdecadal variation of tropical cyclone genesis and its relationship to the monsoon trough over the western North Pacific. Int. J. Climatol., 37, 3587-3596

221.  Huangfu, J., R. Huang, and W. Chen, 2017: Interdecadal increase of tropical cyclone genesis frequency over the western north Pacific in May. Int. J. Climatol., 37, 1127-1130

222.  Huangfu, J., R. Huang, and W. Chen, 2017: Statistical analysis and a case study of tropical cyclones that trigger the onset of the South China Sea summer monsoon. Sci. Rep., 7: 12732, doi: 10.1038/s41598-017-13128-2

223.  Huangfu, J., R. Huang, and W. Chen, 2017: Relationship between the South China Sea summer monsoon onset and tropical cyclone genesis over the western North Pacific. Int. J. Climatol., 37: 5206-5210

224.  Nath, D., W. Chen*, and X. Lan, 2017: Long term trend in potential vorticity intrusion events over the Pacific Ocean: Role of global mean temperature rise. J. Meteor. Res., 31(5), 906-915

225.  Nath, D.*, W. Chen*, H.-F. Graf, X. Lan, and H. Gong, 2017: Contrasting subtropical PV intrusion frequency and their impact on tropospheric Ozone distribution over Pacific Ocean in El-Niño and La-Niña conditions. Sci. Rep., 7, 11987, doi: 10.1038/s41598-017-12278-7

226.  Nath, R., X. Cui, D. Nath, H. F. Graf, W. Chen, L. Wang, H. Gong, and Q. Li, 2017: CMIP5 multimodel projections of extreme weather events in the humid subtropical Gangetic Plain region of India. Earth’s Future, 5, 224-239

227.  Nath, R., D. Nath, Q. Li, W. Chen, and X. F. Cui, 2017: Impact of drought on agriculture in the Indo-Gangetic Plain, India. Adv. Atmos. Sci., 34(3), 335-346

228.  Okoro, U. K., W. Chen, C. Chineke, and O. Nwofor, 2017: Anomalous atmospheric circulation associated with recent West African monsoon rainfall variability. Journal of Geoscicnce and Environment Protection, 5, 1-27

229.  Piao, J. L., W. Chen*, K. Wei, Y. Liu, H.-F. Graf, J.-B. Ahn, and A. Pogoreltsev, 2017: An abrupt rainfall decrease over the Asian inland plateau region around 1999 and the possible underlying mechanism. Adv. Atmos. Sci., 34(4), 456-468

230.  Song, L., S. Chen, W. Chen, and X. Chen, 2017: Distinct impacts of two types of La Niña events on Australian summer rainfall. Int. J. Climatol., 37: 2532–2544

231.  Wang, L., W. Chen, G. Huang, and G. Zeng, 2017: Changes of the transitional climate zone in East Asia: past and future. Clim. Dyn., 49, 1463-1477

232.  Wang, L., P. Xu, W. Chen, and Y. Liu, 2017: Interdecadal variations of the Silk Road pattern. J. Climate, 30, 9915-9932

233.  Xue, X., W. Chen*, and S. Chen, 2017: The climatology and interannual variability of the South Asia high and its relationship with ENSO in CMIP5 models. Clim. Dyn., 48, 3507-3528

234.  Zhong, E. F., Q. Li, S. F. Sun, W. Chen, S. F. Chen, and D. Nath, 2017: Improvement of a snow albedo parameterization in the Snow-Atmosphere-Soil Transfer model: evaluation of impacts of aerosol on seasonal snow cover. Adv. Atmos. Sci., 34(11), 1333-1345

235.  Zhong, E. F., Q. Li, S. F. Sun, S. F. Chen, and W. Chen, 2017: Analysis of euphotic depth in snow with SNICAR transfer scheme. Atmos. Sci. Let., 18, 484-490

236.  Chen Zeyu, Xu Jiyao, Hu Xiong, Chen Hongbin, Chen Wen, et al., 2016: Advances in the researches of the middle and upper atmosphere in China in 2014-2016. Chinese Journal of Space Science, 36(5): 738-752

237.  Chen, S., R. Wu, W. Chen, B. Yu, and X. Cao, 2016: Genesis of westerly wind bursts over the equatorial western Pacific during the onset of the strong 2015-2016 El Niño. Atmos. Sci. Let., 17: 384-391

238.  Nath, D., W. Chen*, H.-F. Graf, X. Lan, H. Gong, R. Nath, K. Hu, and L. Wang, 2016: Subtropical potential vorticity intrusion drives increasing tropospheric ozone over the tropical central Pacific. Sci. Rep., 6, 21370, doi: 10.1038/srep21370

239.  Nath, D., and W. Chen*, 2016: Impact of planetary wave reflection on tropospheric blocking over the Urals-Siberia region in January 2008. Adv. Atmos. Sci., 33(3), 309-318

240.  Nath, D., W. Chen, Z. Cai, A. I. Pogoreltsev, and K. Wei, 2016: Dynamics of 2013 sudden stratospheric warming events and its impact on cold weather over Eurasia: Role of planetary wave reflection. Sci. Rep., 6: 24174, doi: 10.1038/srep24174

241.  Song, L., L. Wang, W. Chen, and Y. Zhang, 2016: Intraseasonal variation of the strength of the East Asian trough and its climatic impacts in boreal winter. J. Climate, 29, 2558-2577

242.  Wang, L., W. Chen*, W. Zhou, and G. Huang, 2016: Understanding and detecting super-extreme droughts in Southwest China through an integrated approach and index. Q. J. R. Meteorol. Soc., 142, 529-535

243.  Wang, L., G. Huang, W. Zhou, and W. Chen, 2016: Historical change and future scenarios of sea level rise in Macau and adjacent waters. Adv. Atmos. Sci., 33(4), 462-475

244.  Zhang, J., L. Wang, S. Yang, W. Chen, and J. Huangfu, 2016: Decadal changes of the wintertime tropical tropospheric temperature and their influences on the extratropical climate. Sci. Bull., 61(9): 737-744

245.  陈尚锋，陈文. 2016. 北极涛动对ENSO影响的研究进展. 气象科技进展，6（5）：6-13

246.  肖晓, 陈文*, 范广洲，周定文. 2016. 20世纪90年代末东亚冬季风年代际变化的外强迫因子分析[J]. 气候与环境研究, 21（2）：197-209

247.  徐霈强，冯娟，陈文. 2016. ENSO冷暖位相影响东亚冬季风与东亚夏季风联系的非对称性. 大气科学，40（4）：831-840

248.  丁硕毅，温之平，陈文*. 2016. 南海夏季风爆发与热带太平洋两类海温型关系的年代际差异. 大气科学，40（2）：243-256

249.  黄荣辉，皇甫静亮，刘永，杜振彩，陈国森，陈文，陆日宇. 2016. 从Rossby波能量频散理论到准定常行星波动力学研究的发展. 大气科学，40（1）：3-21

250.  Cao, X., S. F. Chen, G. H. Chen, W. Chen, and R. G. Wu, 2015: On the weakened relationship between spring Arctic Oscillation and following summer tropical cyclone frequency over the western North Pacific: A comparison between 1968-1986 and 1989-2007. Adv. Atmos. Sci., 32(10), 1319-1328

251.  Chen, S., W. Chen*, and R. Wu, 2015: An interdecadal change in the relationship between boreal spring Arctic Oscillation and the East Asian summer monsoon around the early 1970s. J. Climate, 28, 1527-1542

252.  Chen, S., B. Yu, W. Chen*, 2015: An interdecadal change in the influence of the spring Arctic Oscillation on the subsequent ENSO around the early 1970s. Clim. Dyn., 44, 1109-1126

253.  Chen, S., R. Wu, W. Chen*, and B. Yu, 2015: Influence of the November Arctic Oscillation on the subsequent tropical Pacific sea surface temperature. Int. J. Climatol., 35: 4307-4317

254.  Chen, S., R. Wu, and W. Chen, 2015: The changing relationship between interannual variations of the North Atlantic Oscillation and northern tropical Atlantic SST. J. Climate, 28, 485-504

255.  Chen, Z., R. Wu, and W. Chen, 2015: Effects of northern and southern components of the East Asian winter monsoon variability on SST changes in the western North Pacific. J. Geophys. Res. Atmos., 120, 3888-3905

256.  Feng, J., P. Liu, W. Chen, and X. Wang, 2015: Contrasting Madden-Julian Oscillation activity during various stages of EP and CP El Niños. Atmospheric Science Letters, 16, 32-37

257.  Gong, H., L. Wang, W. Chen, D. Nath, G. Huang, and W. Tao, 2015: Diverse influences of ENSO on the East Asian-western Pacific winter climate tied to different ENSO properties in CMIP5 models. J. Climate, 28, 2187-2202

258.  Huangfu, J.-L., R. H. Huang, and W. Chen, 2015: Influence of tropical western Pacific warm pool thermal state on the interdecadal change of the onset of the South China Sea summer monsoon in the late-1990s. Atmos. Oceanic Sci. Lett., 8, 95-99

259.  Mei, S. L., T. Li, and W. Chen, 2015: Three-type MJO initiation processes over the Western Equatorial Indian Ocean. Adv. Atmos. Sci., 32(9), 1208-1216

260.  Mei, S. L., W. Chen, and S.-F. Chen, 2015: On the relationship between the northern limit of southerly wind and summer precipitation over East China. Atmos. Oceanic Sci. Lett., 8, 52-56

261.  Nath, D., W. Chen, and A. Guharay, 2015: Climatology of stratospheric gravity waves and their interaction with zonal mean wind over the tropics using GPS RO and ground-based measurements in the two phases of QBO. Theor. Appl. Climatol., 119, 757-769

262.  Nath, R., Y. Luan, W. Yang, C. Yang, W. Chen, Q. Li, and X. Cui*, 2015: Changes in arable land demand for food in India and China: A potential threat to food security. Sustainability, 7, 5371-5397

263.  Pogoreltsev, A. I., E. N. Savenkova, O. G. Aniskina, T. S. Ermakova, W. Chen, and K. Wei, 2015: Interannual and intraseasonal variability of stratospheric dynamics and stratosphere-troposphere coupling during northern winter. Journal of Atmospheric and Solar-Terrestrial Physics, 136, 187-200

264.  Wang, L., W. Chen*, W. Zhou, and G. Huang, 2015: Teleconnected influence of tropical Northwest Pacific sea surface temperature on interannual variability of autumn precipitation in Southwest China. Clim. Dyn., 45: 2527-2539

265.  Wang, L., W. Chen, W. Zhou, and G. Huang, 2015: Drought in Southwest China: A review. Atmos. Oceanic Sci. Lett., 8, 339-344

266.  Wei, K., M. Takahashi, and W. Chen, 2015: Long-term changes in the relationship between stratospheric circulation and East Asian winter monsoon. Atmospheric Science Letters, 16: 359-365

267.  Xue, X., W. Chen*, S. Chen, and D. Zhou, 2015: Modulation of the connection between boreal winter ENSO and the South Asian High in the following summer by the stratospheric Quasi-biennial Oscillation. J. Geophys. Res. Atmos., 120, 7393-7411

268.  Xue, X., W. Chen*, D. Nath, and D. Zhou, 2015: Whether the decadal shift of South Asia High intensity around the late 1970s exists or not? Theor. Appl. Climatol., 120, 673-683

269.  余广昌, 陈文, 徐霈强，马音. 2015. 东海黑潮区潜热变化对中国春季降水的影响及其影响过程[J]. 气候与环境研究, 20 (5): 600–610

270.  薛旭，陈文. 2015. 南亚高压在中南半岛上空建立过程及其与亚洲南部夏季风建立的关系. 大气科学，39（4）：705-721

271.  Cao, X., T. Li, M. Peng, W. Chen, and G. Chen, 2014: Effects of monsoon trough intraseasonal oscillation on tropical cyclogenesis over the western North Pacific. J. Atmos. Sci., 71, 4639-4660

272.  Cao, X., T. Li, M. Peng, W. Chen, and G. Chen, 2014: Effects of monsoon trough interannual variation on tropical cyclogenesis over the western North Pacific. Geophys. Res. Lett., 41, 4332-4339

273.  Cao Xi, Chen Guanghua, Huang Ronghui, and Chen Wen, 2014: The intensity variation of the summer intertropical convergence zone in western North Pacific and its impact on tropical cyclones. Journal of Tropical Meteorology, 20(3): 66-74

274.  Chen, S., W. Chen*, and B. Yu, 2014: Asymmetric influence of boreal spring Arctic Oscillation on subsequent ENSO. J. Geophys. Res. Atmos., 119, 11135-11150

275.  Chen, S., K. Wei, W. Chen*, and L. Song, 2014: Regional changes in the annual mean Hadley circulation in recent decades. J. Geophys. Res. Atmos., 119, 7815-7832

276.  Chen, S., B. Yu, W. Chen, 2014: An analysis on the physical process of the influence of AO on ENSO. Clim. Dyn., 42, 973-989

277.  Chen, S., X. Chen, K. Wei, W. Chen, and T. Zhou, 2014: Vertical tilt structure of East Asian trough and its interannual variation mechanism in boreal winter. Theor. Appl. Climatol., 115, 667-683

278.  Chen, Z., R. Wu, and W. Chen, 2014: Distinguishing interannual variations of the northern and southern modes of the East Asian winter monsoon. J. Climate, 27, 835-851

279.  Chen, Z., R. Wu, and W. Chen, 2014: Impacts of autumn Arctic sea ice concentration changes on the East Asian winter monsoon variability. J. Climate, 27, 5433-5450

280.  Chen Zeyu, Chen Hongbin, Xu Jiyao, Bian Jianchun, Qie Xiushu, Lu Daren, Chen Wen, et al., 2014: Advances in researches of the middle and upper atmosphere in China in 2012-2014. Chinese Journal of Space Science, 34(5): 669-687

281.  Feng, J., and W. Chen, 2014: Influence of the IOD on the relationship between El Niño Modoki and the East Asian-western North Pacific summer monsoon. Int. J. Climatol., 34, 1729-1736

282.  Feng, J., and W. Chen, 2014: Interference of the East Asian winter monsoon in the impact of ENSO on the East Asian summer monsoon in decaying phases. Adv. Atmos. Sci., 31(2), 344-354

283.  Feng, J., L. Wang, and W. Chen, 2014: How does the East Asian summer monsoon behave in the decaying phase of El Niño during different PDO phases? J. Climate, 27, 2682-2698

284.  Gong, H., L. Wang, W. Chen*, R. Wu, K. Wei, and X. Cui, 2014: The climatology and interannual variability of the East Asian winter monsoon in CMIP5 models. J. Climate, 27, 1659-1678

285.  Liu, Y. Y., L. Wang*, W. Zhou, and W. Chen*, 2014: Three Eurasian teleconnection patterns: spatial structures, temporal variability, and associated winter climate anomalies. Clim. Dyn., 42: 2817-2839

286.  Nath, D., W. Chen*, L. Wang, and Y. Ma, 2014: Planetary wave reflection and its impact on tropospheric cold weather over Asia during January 2008. Adv. Atmos. Sci., 31(4), 851-862

287.  Nath, R., X. Cui, Y. Luan, W. Yang, Q. Li, and W. Chen, 2014: Historical changes in land requirements for food in India. Indian Journal of Applied Research, 4(12), 11-21

288.  Okoro, U. K., W. Chen, C. Chineke, and O. Nwofor, 2014: Comparative analysis of gridded datasets and gauge measurements of rainfall in the Niger delta region. Research Journal of Environmental Sciences, 8(7), 373-390

289.  Okoro, U. K., W. Chen, T. C. Chineke, and O. K. Nwofor, 2014: Recent monsoon rainfall characteristics over the Niger delta region of Nigeria: A casual link. International Journal of Sciences, Environment and Technology, 3(2), 634-651

290.  Tan Benkui, and Chen Wen*, 2014: Progress in the study of the dynamics of extratropical atmospheric teleconnection patterns and their impacts on East Asian climate. J. Meteor. Res., 28(5), 780-802. 谭本馗，陈文*. 2014. 中高纬度大气遥相关动力学及其对东亚冬季气候影响的研究进展. 气象学报，72（5）：908-925

291.  Wang, L., and W. Chen*, 2014: A CMIP5 multimodel projection of future temperature, precipitation, and climatological drought in China. Int. J. Climatol., 34, 2059-2078

292.  Wang, L., W. Chen*, and W. Zhou, 2014: Assessment of future drought in Southwest China based on CMIP5 multimodel projections. Adv. Atmos. Sci., 31(5), 1035-1050

293.  Wang, L., and W. Chen*, 2014: Equiratio cumulative distribution function matching as an improvement to the equidistant approach in bias correction of precipitation. Atmospheric Science Letters, 15, 1-6

294.  Wang, L., and W. Chen, 2014: An intensity index for the East Asian winter monsoon. J. Climate, 27, 2361-2374

295.  Wang, L., and W. Chen, 2014: The East Asian winter monsoon: re-amplification in the mid-2000s. Chin. Sci. Bull., 59(4), 430-436. 王林，陈文. 2014. 21世纪初东亚冬季风的年代际增强及其成因. 科学通报，59（19），1905

296.  Wu, R., W. Chen, G. Wang, and K. Hu, 2014: Relative contribution of ENSO and East Asian winter monsoon to the South China Sea SST anomalies during ENSO decaying years. J. Geophys. Res. Atmos., 119, 5046-5064

297.  任晓倩，李倩，陈文，刘辉志. 2014. 一个新的湖-气热传输模型及其模拟能力评估. 大气科学，38（5）：993-1004

298.  周群，陈文*. 2014. 太阳活动11年周期对东亚冬季风与随后东亚夏季风关系的影响及其过程. 气候与环境研究，19（4），486-496

299.  王林，陈文. 2014. 标准化降水蒸散指数在中国干旱监测的适用性分析. 高原气象. 33（2）：423-431

300.  胡丽华，李江南，温之平，陈文，吴乃庚. 2014. 南海地区定常行星波特征及其与南海夏季风的关系. 热带气象学报，30（4）：747-754

301.  Cao, X., G. Chen, and W. Chen, 2013: Tropical cyclogenesis induced by ITCZ breakdown in association with synoptic wave train over the western North Pacific. Atmos. Sci. Let., 14, 294-300

302.  Chen, S., W. Chen*, B. Yu, and H.-F. Graf, 2013: Modulation of the seasonal footprinting mechanism by the boreal spring Arctic Oscillation. Geophys. Res. Lett., 40, 6384-6389

303.  Chen, S. F., W. Chen, and K. Wei, 2013: Recent trends in winter temperature extremes in eastern China and their relationship with the Arctic Oscillation and ENSO. Adv. Atmos. Sci., 30(6), 1712-1724

304.  Chen, W., J. Feng, and R. Wu, 2013: Roles of ENSO and PDO in the link of the East Asian winter monsoon to the following summer monsoon. J. Climate, 26, 622-635

305.  Chen, W., X. Q. Lan, L. Wang, and Y. Ma, 2013: The combined effects of the ENSO and the Arctic Oscillation on the winter climate anomalies in East Asia. Chin. Sci. Bull., 58, 1355-1362. 陈文，兰晓青，王林，马音. 2013. ENSO和北极涛动对东亚冬季气候异常的综合影响. 科学通报，58，634-641

306.  Cheung, H. N., W. Zhou, Y. Shao, W. Chen, H. Y. Mok, and M. C. Wu, 2013: Observational climatology and characteristics of wintertime atmospheric blocking over Ural-Siberia. Clim. Dyn., 41, 63-79

307.  Nath, D., and W. Chen*, 2013: Investigating the dominant source for the generation of gravity waves during Indian summer monsoon using ground-based measurements. Adv. Atmos. Sci., 30(1), 153-166

308.  Nath, D., S. Sridharan, S. Sathishkumar, S. Gurubaran, and W. Chen, 2013: Lower stratospheric gravity wave activity over Gadanki (13.5°N, 79.2°E) during the stratospheric sudden warming of 2009: Link with potential vorticity intrusion near Indian sector. Journal of Atmospheric and Solar-Terrestrial Physics, 94, 54-64

309.  Wang, Y. H., W. Chen*, J. Y. Zhang, and D. Nath, 2013: Relationship between soil temperature in May over Northwest China and the East Asian summer monsoon precipitation. Acta Meteor. Sinica, 27(5), 716-724

310.  Yuan, F., and W. Chen*, 2013: Roles of the tropical convective activities over different regions in the earlier onset of the South China Sea summer monsoon after 1993. Theor. Appl. Climatol., 113, 175-185

311.  Zhou, Q., W. Chen*, and W. Zhou, 2013: Solar cycle modulation of the ENSO impact on the winter climate of East Asia. J. Geophys. Res. Atmos., 118, 5111-5119

312.  陈文，魏科，王林，周群. 2013. 东亚冬季风气候变异和机理以及平流层过程的影响. 大气科学，37（2），425－438

313.  兰晓青，陈文*. 2013. 2011～2012年冬季欧亚大陆低温严寒事件与平流层北极涛动异常下传的影响. 大气科学，37（4），863－872

314.  曹西，陈光华，黄荣辉，陈文. 2013. 夏季西北太平洋热带辐合带的强度变化特征及其对热带气旋的影响. 热带气象学报，29（2），198－206

315.  王林，陈文. 2013. 误差订正空间分解法在中国的应用. 地球科学进展，28（10）：1144-1153

316.  黄荣辉，周德刚，陈文，周连童，韦志刚，张强，高晓清，卫国安，候旭宏. 2013. 关于中国西北干旱区陆－气相互作用及其对气候影响研究的最近进展. 大气科学，37（2），189－210

317.  任晓倩，孙菽芬，陈文，刘辉志. 2013. 湖泊数值模拟研究现状综述. 地球科学进展，28（3），347－356

318.  Cao, X., P. Huang, G. H. Chen, and W. Chen, 2012: Modulation of western North Pacific tropical cyclone genesis by intraseasonal oscillation of the ITCZ: A statistical analysis. Adv. Atmos. Sci., 29(4), 744-754

319.  Chen, W., and Q. Zhou, 2012: Modulation of the Arctic Oscillation and the East Asian winter climate relationships by the 11-year solar cycle. Adv. Atmos. Sci., 29(2), 217-226

320.  Chen Zeyu, Chen Hongbin, Liu Xiao, Hu Xiong, Bian Jianchun, Chen Wen, et al., 2012: Advances in researches on the middle and upper atmosphere in 2010-2012. Chinese Journal of Space Science, 32(5): 681-692

321.  Lan, X. Q., W. Chen*, and L. Wang, 2012: Quasi-stationary planetary wave-mean flow interactions in the Northern Hemisphere stratosphere and their responses to ENSO events. Sci. China Earth Sci., 55, 405-417. 兰晓青，陈文*，王林. 2012. 北半球平流层准定常行星波与平均流的相互作用及其对ENSO事件的响应. 中国科学，42（1）：10－23

322.  Wang, L., K. Kodera, and W. Chen, 2012: Observed triggering of tropical convection by a cold surge: implications for MJO initiation. Q. J. R.. Meteorol. Soc., 138, 1740-1750

323.  Wei, K., and W. Chen, 2012: Northern Hemisphere stratospheric polar vortex extremes in February under the control of downward wave flux in the lower stratosphere. Atmos. Oceanic Sci. Lett., 5, 183-188

324.  Wu, R., J.-L. Chen, and W. Chen, 2012: Different types of ENSO influences on the Indian summer monsoon variability. J. Climate, 25, 903-920

325.  Wu, R., X. Cao, and W. Chen, 2012: Surface wind speed-SST relationship during the passage of typhoons over the South China Sea. IEEE Geoscience and Remote Sensing Letters, 9(5), 933-937

326.  Yuan, F., W. Chen*, and W. Zhou, 2012: Analysis of the role played by circulation in the persistent precipitation over South China in June 2010. Adv. Atmos. Sci., 29(4), 769-781

327.  Zhou, W., W. Chen, and D. Wang, 2012: The implications of El Niño-Southern Oscillation signal for South China monsoon climate. Aquatic Ecosystem Health & Management, 15, 14-19

328.  周群，陈文*. 2012. 太阳活动11年周期对ENSO事件海温异常演变和东亚降水的影响. 大气科学. 36（4）：851－862

329.  王远皓，陈文，张井勇. 2012. 东亚中纬度干旱/半干旱区降水年际变化及其可能成因，气候与环境研究，17（4）：444－456

330.  刘毓赟，陈文. 2012. 北半球冬季欧亚遥相关型的变化特征及其对我国气候的影响. 大气科学，36(2): 423-432

331.  马音，陈文，冯瑞权，梁嘉静，梁永权. 2012. 我国东部梅雨期降水的年际和年代际变化特征及其与大气环流和海温的关系. 大气科学，36(2): 397-410

332.  王林，陈文. 2012. 近百年西南地区干旱的多时间尺度演变特征. 气象科技进展，2(4): 21-26

333.  陈国森，王林，陈文. 2012. 大气Rossby长波理论的建立和发展. 气象科技进展，2(6): 50-54

334.  Feng, J., W. Chen*, C.-Y. Tam, and W. Zhou, 2011: Different impacts of El Niño and El Niño Modoki on China rainfall in the decaying phases. Int. J. Climatol., 31, 2091-2101

335.  Wei, K., and W. Chen, 2011: An abrupt increase in the summer high temperature extreme days across China in the mid-1990s. Adv. Atmos. Sci., 28(5), 1023-1029

336.  Wei, K., W. Chen, and W. Zhou, 2011: Changes in the East Asian cold season since 2000. Adv. Atmos. Sci., 28(1), 69-79

337.  陈尚锋，温之平，陈文*. 2011. 南海地区大气30－60天低频振荡及其对南海夏季风的可能影响. 大气科学，35（5）：982－992

338.  马音，陈文，王林. 2011. 中国夏季淮河和江南梅雨期降水异常年际变化的气候背景及其比较. 气象学报，69：334－343

339.  王林，陈文，冯瑞权，梁嘉静. 2011. 北太平洋涛动的季节演变及其与我国冬春气候异常的联系. 大气科学，35（3）：393－402

340.  Chen Zeyu, Chen Hongbing, Lu Daren, Xu Jiyao, Chen Wen, et al., 2010: Advances in researches on the middle and upper atmosphere in 2008-2010. Chinese Journal of Space Science, 30(5): 456-463

341.  Feng, J., L. Wang, W. Chen*, S. K. Fong, and K. C. Leong, 2010: Different impacts of two types of Pacific Ocean warming on Southeast Asian rainfall during boreal winter. J. Geophys. Res., 115, D24122, doi:10.1029/2010JD014761

342.  Gu, Y., K. N. Liou, W. Chen, and H. Liao, 2010: Direct climate effect of black carbon in China and its impact on dust storms. J. Geophys. Res., 115, D00K14, doi:10.1029/2009JD013427

343.  Jadin, E. A., K. Wei, Y. A. Zyulyaeva, W. Chen, and L. Wang, 2010: Stratospheric wave activity and the Pacific Decadal Oscillation. Journal of Atmospheric and Solar-Terrestrial Physics, 72, 1163-1170

344.  Wang, L., W. Chen*, W. Zhou, J. C. L. Chan, D. Barriopedro, and R. Huang, 2010: Effect of the climate shift around mid 1970s on the relationship between wintertime Ural blocking circulation and East Asian climate. Int. J. Climatol., 30, 153-158

345.  Wang, L., and W. Chen, 2010: How well do existing indices measure the strength of the East Asian winter monsoon? Adv. Atmos. Sci., 27(4), 855-870

346.  Wang, L., and W. Chen, 2010: Downward Arctic Oscillation signal associated with moderate weak stratospheric polar vortex and the cold December 2009. Geophys. Res. Lett., 37, L09707, doi:10.1029/2010GL042659

347.  Yuan, F., K. Wei, W. Chen*, S. K. Fong, and K. C. Leong, 2010: Temporal variations of the frontal and monsoon storm rainfall during the first rainy season in South China. Atmos. Oceanic Sci. Lett., 3, 243-247

348.  房云龙，孙菽芬，李倩，陈文*. 2010. 干旱区陆面过程模型参数优化和地气相互作用特征的模拟研究. 大气科学，34：290-306

349.  韦志刚，陈文，黄荣辉. 2010. 敦煌夏末大气垂直结构和边界层高度特征，大气科学，34：905-913

350.  Chen, W., L. Wang, Y. Xue, and S. Sun, 2009: Variabilities of the spring river runoff system in East China and their relations to precipitation and sea surface temperature. Int. J. Climatol., 29, 1381-1394

351.  Chen, W., and K. Wei, 2009: Interannual variability of the winter stratospheric polar vortex in the northern hemisphere and their relations to QBO and ENSO. Adv. Atmos. Sci., 26(5), 855-863

352.  Chen, W., D. Q. Zhu, H. Z. Liu, and S. F. Sun, 2009: Land-air interaction over arid/semi-arid areas in China and its impact on the East Asian summer monsoon. Part I: Calibration of the Land Surface Model (BATS) using multicriteria methods. Adv. Atmos. Sci., 26(6), 1088-1098

353.  Cui, X., G. Huang, W. Chen, and A. Morse, 2009: Threatening of climate change on water resources and supply: Case study of North China. Desalination, 248, 476-478

354.  Wang, L., W. Chen*, W. Zhou, and R. Huang, 2009: Interannual variations of East Asian trough axis at 500 hPa and its association with the East Asian winter monsoon pathway. J. Climate, 22, 600-614

355.  Wang, L., R. Huang, L. Gu, W. Chen, and L. Kang, 2009: Interdecadal variations of the East Asian winter monsoon and their association with quasi-stationary planetary wave activity. J. Climate, 22, 4860-4872

356.  Wei, K., and W. Chen, 2009: Climatology and Trends of High Temperature Extremes across China in Summer, Atmospheric and Oceanic Science Letters, 2(3), 153-158

357.  Zhou, W., J. C. L. Chan, W. Chen, J. Ling, J. G. Pinto, and Y. Shao, 2009: Synoptic-scale controls of persistent low temperature and icy weather over southern China in January 2008. Mon. Wea. Rev., 137, 3978-3991

358.  陈文，魏科. 2009. 大气准定常行星波异常传播及其在平流层影响东亚冬季气候中的作用. 地球科学进展，24：272-285

359.  康丽华，陈文，王林，陈丽娟. 2009. 我国冬季气温的年际变化及其与大气环流和海温异常的关系. 气候与环境研究，14：45-53

360.  周长春，高晓清，陈文，惠小英，李洁. 2009. 中亚感热异常对我国西北温度、降水的影响. 高原气象，28：395-401

361.  Chen Zeyu, Chen Hongbin, Chen Wen, Lu Daren, 2008: Advances in the researches in middle and upper atmosphere in 2006-2008, Chin. J. Space Sci., 28(5): 412-423

362.  Cui, X., G. Huang, and W. Chen, 2008: Notes of numerical simulation of summer rainfall in China with a regional climate model REMO. Adv. Atmos. Sci., 25(6), 999-1008

363.  Wang, L., W. Chen*, and R. Huang, 2008: Interdecadal modulation of PDO on the impact of ENSO on the East Asian winter monsoon. Geophys. Res. Lett., 35, L20702, doi: 10.1029/2008GL035287

364.  陈文，顾雷，魏科，黄荣辉. 2008. 东亚季风系统的动力过程和准定常行星波活动的研究进展. 大气科学，32：950-966

365.  魏科，陈文，黄荣辉. 2008. 涡动在南北半球平流层极涡崩溃过程中作用的比较. 大气科学，32：206-219

366.  韦志刚，陈文，黄荣辉. 2008. 青藏高原冬春积雪异常影响中国夏季降水的数值模拟，高原山地气象研究. 28（1）：1-7

367.  曲迎乐，高晓清，陈文，惠小英，周长春. 2008. 近50年来我国东、西部地面气温和降水变化对比的初步分析，高原气象，27（3）：524-529

368.  曾庆存，周广庆，浦一芬，陈文，李荣风，廖宏，林朝晖，刘辉志，王必正，谢正辉，徐永福，薛峰，曾晓东，张风. 2008. 地球系统动力学模式及模拟研究. 大气科学，32（4）：653-690

369.  Chen, W., and T. Li, 2007: Modulation of northern hemisphere wintertime stationary planetary wave activity: East Asian climate relationships by the Quasi-Biennial Oscillation. J. Geophys. Res., 112, D20120, doi: 10.1029/2007JD008611

370.  Cui, X., H. -F. Graf, B. Langmann, W. Chen, and R. Huang, 2007: Hydrological Impacts of Deforestation on the Southeast Tibetan Plateau. Earth Interactions, 11, 1-18

371.  Wang, L., W. Chen*, and R. Huang, 2007: Changes in the variability of North Pacific Oscillation around 1975/1976 and its relationship with East Asian winter climate. J. Geophys. Res., 112, D11110, doi: 10.1029/2006JD008054

372.  Wei, K., W. Chen*, and R. Huang, 2007: Association of tropical Pacific sea surface temperatures with the stratospheric Holton-Tan Oscillation in the Northern Hemisphere winter. Geophys. Res. Lett., 34, L16814, doi: 10.1029/2007GL030478

373.  Wei, K., W. Chen, and R. Huang, 2007: Dynamical diagnosis of the breakup of the stratospheric polar vortex in the Northern Hemisphere. Science in China Series D: Earth Sciences, 50(9): 1369-1379. 魏科，陈文，黄荣辉. 2007. 北半球平流层极涡崩溃过程的动力诊断分析. 中国科学D辑：地球科学，37（08）：1110-1119

374.  王林，陈文，黄荣辉，黄刚, 2007. 北半球定常波输送西风动量的气候态及其年变化. 大气科学，31：377-388

375.  简茂球，乔云亭，罗会邦，陈文, 2007. 初夏东亚-太平洋大气热源与长江流域及邻近地区7、8月降水异常的关系. 大气科学，31：735-746

376.  简茂球，陈文，乔云亭，罗会邦, 2007. 中国汛期月降水量年际异常型的相关性分析. 热带气象学报，23：333-340

377.  黄荣辉，魏科，陈际龙，陈文. 2007. 东亚2005年和2006年冬季风异常及其与准定常行星波活动的关系. 大气科学，31：1033-1048

378.  温之平，董灵英，吴丽姬，陈文, 2007. 大气30-60d振荡特征及其与广东持续性强降水的联系. 中山大学学报，46：98-103

379.  Chen Zeyu, Liu Renqiang, Chen Hongbin, Chen Wen, Lu Daren, Xu jiyao, Hu Xiong, 2006: Advances in the studies of the middle and upper atmosphere in 2004-2006, Chin.. J. Space Sci., 26(supp): 61-70

380.  Cui, X. F., H.-F. Graf, B. Langmann, W. Chen, and R. Huang, 2006: Climate impacts of anthropogenic land use changes on the Tibetan Plateau. Glob. Planet. Change, 54, 33-56

381.  Wei, K., W. Chen, and R. Huang, 2006: Long-term changes of the ultraviolet radiation in China and its relationship with total ozone and precipitation. Adv. Atmos. Sci., 23(5), 700-710

382.  陈文，康丽华（2006），北极涛动与东亚冬季气候在年际尺度上的联系：准定常行星波的作用，大气科学，30：863-870

383.  陈文（2006），北半球冬季准定常行星波传播的年代际变化，自然科学进展，16：485-489

384.  陈文，康丽华，王玎（2006），我国夏季降水与全球海温的耦合关系分析，气候与环境研究，11：259-269

385.  康丽华，陈文，魏科（2006），我国冬季气温年代际变化及其与大气环流异常变化的关系，气候与环境研究，11：330-339

386.  韦志刚，黄荣辉，陈文（2006），敦煌戈壁不同近地层大气稳定度下的感热交换系数，高原气象，25：834-839

387.  杨蕾，陈文，黄荣辉（2006），北半球准定常行星波气候平均态的资料分析和数值模拟，大气科学，30：361-376

388.  朱德琴，陈文，刘辉志，黄荣辉（2006），我国西北典型干旱区和高原地区地表辐射能量收支特征的比较，气候与环境研究，11：683-690

389.  朱德琴，高晓清，陈文（2006），陆面模式（SSiB）对敦煌荒漠戈壁下垫面陆面过程的模拟及敏感性试验，中国沙漠，26：466-472

390.  Chen, W., S. Yang*, and R.-H. Huang, 2005: Relationship between stationary planetary wave activity and the East Asian winter monsoon. J. Geophys. Res., 110, D14110, doi: 10.1029/2004JD005669

391.  陈文，黄荣辉（2005），北半球冬季准定常行星波的三维传播及其年际变化，大气科学，29：137-146

392.  杨蕾，陈文，黄荣辉（2005），关于北半球准定常行星波年际变化的资料分析和数值模拟，大气科学，29：682-696

393.  韦志刚，黄荣辉，陈文（2005），青藏高原冬春积雪年际振荡成因分析，冰川冻土，27：491-497

394.  Huang, R., W. Chen, B. Yan, and R. Zhang, 2004: Recent advances in studies of the interaction between the East Asian winter and summer monsoon and ENSO cycle. Adv. Atmos. Sci., 21, 407-424

395.  陈文，杨蕾，黄荣辉，邱启鸿（2004），热带准两年震荡影响北半球冬季大气环流的诊断分析，大气科学，28：161-173

396.  Chen, W., M. Takahashi, and H.–F. Graf, 2003: Interannual variations of stationary planetary wave activity in the northern winter troposphere and stratosphere and their relations to NAM and SST. J. Geophys. Res., 108(D24), 4797, doi: 10.1029/2003JD003834

397.  Huang, R., L. Zhou, and W. Chen, 2003: The progresses of recent studies on the variabilities of the East Asian monsoon and their causes. Adv. Atmos. Sci., 20, 55-69

398.  黄荣辉，陈文，丁一汇，李崇银（2003），关于季风动力学以及季风与ENSO循环相互作用的研究，大气科学，27：484-502

399.  Chen, W., Hans-F. Graf, and M. Takahashi, 2002: Observed interannual oscillations of planetary wave forcing in the Northern Hemisphere winter. Geophys. Res. Lett., 29(22), 2073, doi: 10.1029/2002GL016062

400.  Chen, W., and R. Huang, 2002: The propagation and transport effect of planetary waves in the Northern Hemisphere winter. Adv. Atmos. Sci., 19, 1113-1126

401.  陈文（2002），El Niño和  La Niña事件对东亚冬、夏季风循环的影响，大气科学，26：595-610

402.  黄荣辉，陈文（2002），关于亚洲季风与ENSO循环相互作用研究最近的进展，气候与环境， 7：146-159

403.  韦志刚，黄荣辉，陈文，董文杰 （2002），青藏高原地面站积雪的空间分布和年代际变化特征，大气科学，26：496-508

404.  Chen, W., Hans-F. Graf, and R. Huang, 2000: The interannual variability of East Asian winter monsoon and its relation to the summer monsoon. Adv. Atmos. Sci., 17, 48-60

405.  Chen, W., and R.-H. Huang (1999), The modulation of planetary wave propagation by the tropical QBO zonal winds and the associated effects in the residual meridional circulation. Contr. Atmos. Phys., 72(2), 187-204

406.  Cheng Anning, Chen Wen and Huang Ronghui (1998), The sensitivity of numerical simulation of the East Asian monsoon to different cumulus parameterization schemes. Adv. Atmos. Sci., 15, 204-220

407.  成安宁，陈文，黄荣辉 （1998），积云对流参数化方案对气候数值模拟的影响，大气科学， 22：814-824

408.  陈文，黄荣辉 （1996），中层大气行星波在臭氧的季节和年际变化中输运作用的数值研究（II）波流相互作用的情况，大气科学，20：703-712

409.  陈文，黄荣辉 （1996），中层大气行星波在臭氧的季节和年际变化中输运作用的数值研究（I）定常流的情况，大气科学，20：513-523

410.  陈文，黄荣辉（1995），准定常行星波对大气中臭氧输运的动力作用，大气科学，19：513-524

 

（更新于2023-2-28）