温之平
特聘教授/博士生导师
zpwen@fudan.edu.cn
研究兴趣
气候动力学、大尺度海-气和陆-气相互作用、季风气象学、台风气候学、极端天气气候
教育背景
学士学位(1984年),气象学,杭州大学(现浙江大学)
硕士学位(1990年),天气动力学,中山大学
博士学位(2006年),气象学,中国科学院大气物理研究所
工作经历
2018年 8月 - 至今,特聘教授,yh86银河国际
2009年9月 - 2018年7月,主任,中山大学季风与环境研究中心
2000年7月 - 2015年10月,系主任,中山大学大气科学系
1997年9月 - 2000年6月,副系主任,中山大学大气科学系
1990年7月 - 2018年7月,助教、讲师、副教授、教授,中山大学大气科学系
1984年7月 - 1987年8月,助教,江西农业大学气象教研室
教学经历
1993年2月 - 2017年6月,热带气象学,本科生,中山大学
2003年2月 - 2017年6月,热带大气动力学,研究生,中山大学
2019年2月 - 至今,热带气象学,本科生,yh86银河国际
学术兼职
兼任国际气象学和大气科学协会中国委员会(CNC-IAMAS)委员、世界气候研究计划中国国家委员会(CNC-WCRP)委员、全球能量与水分循环计划中国委员会(CNC-GEWEX)委员;中国气象学会理事、中国气象学会热带气象委员会副主任委员、中国气象学会气候学委员会委员、中国气象学会动力气象学委员会委员、中国气象学统计气象学与气候预测委员会委员、中国气象学会气象教育与培训委员会委员、上海市气象学会副理事长;《中国科学•地球科学》(中英文版)、《Advances in Atmospheric Sciences》、《大气科学》、《大气科学学报》、《高原气象》、《气象科技》等杂志编委。
承担的主要课题
(1)重点项目:对流层高层热带东风急流中心位置的变化及机制(42030601),300.00万元,主持,2021年1月 – 2025年12月。
(2)面上项目:夏季低频东亚-太平洋遥相关型的特征、形成和维持机制及影响(41875087),62万元,主持,2019年1月 – 2022年12月
(3)重点项目:全球变暖背景下南海夏季风系统年代变化及其机制(41530530),260万元,主持,2016年1月 – 2020年12月。
(4)面上项目:春季欧亚中高纬大气环流异常对南海夏季风爆发的影响(41175076),80万元,主持, 2012年1月 – 2015年12月。
(5)重点项目:华南干旱成因及预测理论研究(40730951),经费160万元,主持,2008年1月 – 2011年12月。
(6)面上项目:南海夏季风建立迟早年际变化的机制研究,经费27万元,主持2003年1月 – 2005年12月。
(1)国家重点研发计划(全球变化与应对专项)课题:全球变暖背景下东亚夏季风系统的变化特征(2016YFA0600601),562.5万元,主持,2016年7月 – 2021年6月。
(2)国家重点基础研究发展规划(973项目)课题:东亚季风湿润区和西太平洋的能量和水分循环的观测试验与分析研究(2009CB421404),经费363.0万元,主持,2008年11月 – 2013年9月。
近十年发表的主要论文
(本人名字加粗,通讯作者加*号)
(1)Zhao Y., Z. Wen, and X. Li, 2021: Structure and Maintenance Mechanisms of the Mascarene High in Austral Winter. International Journal of Climatology, doi:10.1002/joc.7498.
(2)Li Y., Z. Wen*, and W. Tian, 2021: The influence of the enhancement of convective activity of tropical Pacific on the trend of stratospheric sudden warmings in the period of 1948-2003. Climate Dynamics, doi:10.1007/s00382-021-06021-2.
(3)Li Y., and Z. Wen*, 2021: The influence of interdecadal changes in boreal winter teleconnections around the 1980s on planetary waves and stratospheric sudden warmings. Journal of Geophysical Research: Atmospheres, 126, e2021JD035341, doi:10.1029/2021JD035341.
(4)Chen R., Z. Wen, R. Lu, and W. Liu, 2021: Interdecadal changes in the interannual variability of the summer temperature over Northeast Asia, Journal of Climate, 34, 8361-8376, doi:10.1175/JCLI-D-21-0115.1.
(5)Huang S., B. Wang, Z. Wen*, and Z. Chen, 2021: Enhanced Tropical Eastern Indian Ocean Rainfall Breaks down the Tropical Easterly Jet-Indian Rainfall Relationship. Journal of Climate, 34. 3039-3048, doi:10.1175/JCLI-D-20-0631.1.
(6)Zhu Y., Z. Wen*, Y. Guo, R. Chen, X. Li, and Y. Qiao, 2020: The Characteristics and Possible Growth Mechanisms of the Quasi-Biweekly Pacific–Japan Teleconnection in Boreal Summer. Climate Dynamics. 55, 3363-3380, doi:10.1007/s00382-020-05448-3.
(7)Huang S., X. Li, and Z. Wen, 2020: Characteristics and Possible Sources of the intraseasonal South Asian Jet Wave Train in Boreal Winter. Journal of climate. 33(24), 10523–10537, doi:10.1175/JCLI-D-20-0125.1.
(8)Guo Y., Z. Wen*, Y. Tan, and X. Li, 2020: Plausible causes of the interdecadal change of the North Pacific teleconnection pattern in boreal spring around the late 1990s. Climate Dynamics, 55(5), 1427-1442, doi:10.1007/s00382-020-05334-y.
(9)Huang S., B. Wang, and Z. Wen, 2020: Dramatic Weakening of the Tropical Easterly Jet Projected by CMIP6 Models. Journal of Climate. 33, 8439-8455, doi:10.1175/JCLI-D-19-1002.1.
(10)Li X., Z. Wen, W. Huang, 2020: Modulation of South Asian Jet wave train on the Extreme Winter Precipitation over Southeast China: Comparison between 2015/16 and 2018/19. Journal of Climate, 33, 4065-4081, doi:10.1175/JCLI-D-19-0678.1.
(11)Guo Y., Z. Wen*, and X. Li, 2020: Interdecadal Change in the Principal Mode of Winter-Spring Precipitation Anomaly over Tropical Pacific around the Late 1990s. Climate Dynamics. 54, 1023-1042, doi:10.1007/s00382-019-05042-2.
(12)Zhang H., Z. Wen*, R. Wu, R. Chen, and X. Li, 2019: An inter-decadal increase in summer sea level pressure over the Mongolian region around the early 1990s. Climate Dynamics, 52:3-4, 1935-1948, doi:10.1007/s00382-018-4228-x.
(13)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. Sci China Earth Sci. 62, 1514–1550, doi: 10.1007/s11430-019-9483-5.
(14)Wang J., Z. Wen*, R. Wu and A. Lin, 2017: The impact of tropical intraseasonal oscillation on the summer rainfall increase over southern China around 1992/1993. Climate Dynamics, 49: 1847-1863, doi:10.1007/s00382-016-3425-8.
(15)Chen J., Z. Wen*, R. Wu, X. Wang, and C He, 2017: An interdecdal change in the intensity of interannual variability in summer rainfall over southern China around early 1990s. Climate Dynamics, 48, 191-207, doi:10.1007/s00382-016-3069-8.
(16)Wang J., Z. Wen*, R. Wu, Y. Guo, and Z. Chen, 2016: The mechanism of growth of the low-frequency East Asia-Pacific teleconnection and the triggering role of tropical intraseasonal oscillation. Climate Dynamics, 46(11), 3965-3977, doi:10.1007/s00382-015-2815-7.
(17)Guo Y., Z. Wen*, R. Wu, R. Lu, and Z. Chen, 2015: Impact of tropical Pacific precipitation on the East Asian upper-tropospheric westerly jet during the boreal winter. Journal of Climate, 28(16), 6457-6474, doi:10.1175/JCLI-D-14-00674.1.
(18)Chen J., Z. Wen*, R. Wu and Z. Chen, 2015: Influences of northward propagating 25-90-day and quasi-biweekly oscillations on Eastern China summer rainfall. Climate Dynamics, 45(1), 105-124, doi:10.1007/s00382-014-2334-y.
(19)Feng X., R. Wu, J. Chen, and Z, Wen*, 2013: Factors for interannual variations of September-October rainfall in Hainan, China. Journal of Climate, 26, 8962-8978. doi:10.1175/JCLI-D-12-00728.1.
(20)Wu R., J. Chen, and Z. Wen, 2013: Precipitation-Surface Temperature Relationship in the IPCC CMIP5 Models. Advances in Atmospheric Sciences, 30(3), 2013, 766-778, doi:10.1007/s00376-012-2130-8.
(21)Zhao P., S. Yang, R. Wu, Z. Wen, J. Chen, and H. Wang, 2012: Asian Origin of Interannual Variations of Summer Climate over the Extratropical North Atlantic Ocean. Journal of Climate, 25, 6594-6608, doi:10.1175/JCLI-D-11-00617.1.
(22)Li X., Z. Wen, W. Zhou, and D. Wang, 2012: Atmospheric Water Vapor Transport Associated with Two Decadal Rainfall Shifts over East China. Journal of the Meteorological Society of Japan, 90(5), 587−602, doi:10.2151/jmsj.2012-501.
(23)Cao J., Z. Wen, Y. Chang, and X. Li, 2012: Wavelet analysis of the convectively-coupled equatorial waves. Sci China Earth Sci, 55(4), 675–684, doi:10.1007/s11430-011-4298-7.
(24)Wang T., S. Yang, Z. Wen, R. Wu, and P. Zhao, 2011: Variations of the winter India-Burma Trough and their links to climate anomalies over southern and eastern Asia, J. Geophys. Res. Atmos., 116,D23118, doi:10.1029/2011JD016373.
(25)Li S., Z. Wen, and W. Zhou, 2011: Long-term Change in summer water vapor transport over South China in recent decades. Journal of the Meteorological Society of Japan, 89, 271—282, doi:10.2151/jmsj.2011-A17.
(26)Wu R., Z. Wen, S. Yang, and Y. Li, 2010: An interdecadal change in southern China summer rainfall around 1992-93. Journal of Climate, 23, 2389-2403, doi:10.1175/2009JCLI3336.1
(27)Li J., Z. Wen, X. Li, and Y. Guo, 2021: Interdecadal Changes in the Relationship between Wintertime Surface Air Temperature over the Indo-China Peninsula and ENSO. Journal of Climate, doi:10.1175/JCLI-D-21-0477.1.
(28)Zhang C., Y. Guo, and Z. Wen*, 2021: Interdecadal Change in the Effect of Tibetan Plateau Snow Cover on Spring Precipitation over Eastern China around the Early 1990s. Climate Dynamics, doi:10.1007/s00382-021-06035-w.
(29)Jiang X., Y. Guo, and Z. Wen. 2021: Role of Tropical Diabatic Heating on the Out-of-phase Mode of the Cross-equatorial Flows over the Asian-Australian Monsoon Region in Boreal Summer. Atmospheric and Oceanic Sciences Letters, doi:10.1016/j.aosl.2021.100100.
(30)Chen Z., Z. Li, Y. Du, Z. Wen, R. Wu, and S. Xie, 2021: Trans-Basin Influence of Southwest Tropical Indian Ocean Warming during Early Boreal Summer, Journal of Climate, 34, 9679-9691, doi:10.1175/JCLI-D-20-0925.1
(31)Zhang C., X. Jia, and Z. Wen, 2021: Changes in the Relationship between the Meiyu Rainfall over the Yangtze River Valley and the Tibetan Plateau Spring Snow Cover in the Early 1990s. Journal of Climate, 34, 5985-5997, doi:10.1175/JCLI-21-0009.1.
(32)Zhang R., Y. Guo, Z. Wen, and R. Wu, 2020: Distinct patterns of sea surface temperature anomaly in the South Indian Ocean during austral autumn. Climate Dynamics, 54:2663–2682, doi:10.1007/s00382-020-05135-3.
(33)Huang S., Z. Wen*, Z. Chen, X. Li, R. Chen and Y. Guo, 2019: Interdecadal change in the relationship between the tropical easterly jet and tropical sea surface temperature anomalies in boreal summer. Climate Dynamics. 53, 2119–2131, doi:10.1007/s00382-019-04801-5.
(34)Chen Z., Y. Du, Z. Wen, R. Wu, and S. Xie, 2019: Evolution of south tropical Indian Ocean warming and the climatic impacts following strong El Niño event. Journal of Climate. 32, 7329-7347, doi:10.1175/JCLI-D-18-0704.1.
(35)Wang Y., R. Wu, and Z. Wen, 2019: Seasonal variations in size and intensity of the Indo-western Pacific warm pool in different sectors. Journal of Oceanography, 75, 423–439, doi:10.1007/s10872-019-00511-y.
(36)Guo Y., Z. Wen*, R. Chen, X. Li and X. Yang, 2019: Effect of boreal spring precipitation anomaly pattern change in the late 1990s over tropical Pacific on the atmospheric teleconnection. Climate Dynamics, 52:1-2, 401-416, doi:10.1007/s00382-018-4149-8.
(37)Li X.,Z. Wen, D. Chen, and Z. Chen, 2019: Decadal transition of the leading mode of interannual moisture circulation over East Asia-Western North Pacific: Bonding to Different Evolution of ENSO. Journal of Climate, 32, 289-308, doi:10.1175/JCLI-D-18-0356.1.
(38)Chen, R., Z. Wen, and R. Lu, 2018: Interdecadal change on the relationship between the mid-summer temperature in South China and atmospheric circulation and sea surface temperature. Climate Dynamics, 51, 2113-2126, doi:10.1007/s00382-017-4002-5.
(39)Li Y., W. Tian, F. Xia, Z. Wen, and J. Zhang, 2018: The Connection between the Second Leading Mode of Winter North Pacific Sea Surface Temperature Anomalies and Stratospheric Sudden Warming Events. Climate Dynamics, 51, 581-595, doi:10.1007/s00382-017-3942.
(40)Chen Z., Y. Du, Z. Wen, R. Wu, and C. Wang, 2018: Indo-Pacific climate during the decaying phase of the 2015/16 El Niño: Role of southeast tropical Indian Ocean warming. Climate Dynamics. 50 (11-12), 4707-4719, doi:10.1007/s00382-017-3899-z.
(41)Chen Z., Z Wen*, R. Wu, and Y. Du, 2017: Roles of tropical SST anomalies in modulating the western north Pacific anomalous cyclone during strong La Nina decaying years. Climate Dynamics, 49 :633-647, doi:10.1007/s00382-016-3364-4.
(42)He Z., R. Wu, W. Wang, Z. Wen, and D. Wang, 2017: Contributions of surface heat fluxes and oceanic processes to tropical SST changes: Seasonal and regional dependence. Journal of Climate, 30, 4185-4205, doi:10.1175/JCLI-D-16-0500.1.
(43)Guo Y., M. Ting, Z. Wen, and D. Lee, 2017: Distinct patterns of Tropical Pacific SST Anomaly and Their Impacts on North American Climate. Journal of Climate, 30(14), 5221-5241, doi:10.1175/JCLI-D-16-0488.1.
(44)Peng B.,Z. Chen,Z. Wen*,and R. Lu, 2016:Impacts of two types of El Niño on MJO during boreal winter. Advances in Atmospheric Sciences, 33(8): 979-986, doi:10.1007/s00376-016-5272-2.
(45)Guo Y., Z. Wen*, and R. Wu, 2016: Interdecadal Change in the Tropical Precipitation Anomaly around the late 1990s during the Boreal Spring. Journal of Climate, 29, 5979-5997, doi:10.1175/JCLI-D-15-0462.1.
(46)Chen Z., Z. Wen*, R. Wu, X. Lin and J. Wang, 2016: Relative Importance of Tropical SST Anomalies in Maintaining the Western North Pacific Anomalous Anticyclone during El Niño to La Niña transition years. Climate Dynamics, 46(3), 1027-1041, doi:10.1007/s00382-015-2630-1.
(47)Chen J., Z. Wen*, R. Wu, and Z. Chen, 2014: Interdecadal Changes in the Relationship between Southern China Winter-spring Precipitation and ENSO. Climate Dynamics, 43(5) ,1327-1338, doi:10.1007/s00382-013-1947-x.
(48)Chen Z., Z. Wen*, R. Wu, P. Zhao, and J. Cao, 2014: Influence of two types of El Niños on the East Asian climate during boreal summer: A numerical study. Climate Dynamics, 43(1), 469-481, doi:10.1007/s00382-013-1943-1.
(49)Wu R., Z. Wen, and Zhouqi He, 2013: ENSO Contribution to Aerosol Variations over the Maritime Continent and the Western North Pacific during 2000-2010. Journal of Climate, 26, 6541-6560, doi:10.1175/JCLI-D-12-00253.1.
(50)Wu R., S. Yang, Z. Wen, G. Huang, and K. Hu, 2012: Interdecadal change in the relationship of southern China summer rainfall with tropical Indo-Pacific SST. Theor. & Appl. Climatol., 108, 119-133, doi:10.1007/s00704-011-0519-4.
(51)Wu W., Z. Wen*, R. Wu, and T. Wang, 2011: Air-sea interaction over the subtropical North Pacific during the ENSO transition phase. Journal of Climate, 24(22), 5772-5785, doi:10.1175/2011JCLI3820.1.
(52)Chen G., Y. Du, and Z. Wen, 2021: Seasonal, interannual and interdecadal variations of the East Asian summer monsoon: A diurnal-cycle perspective. Journal of Climate, 34, 4403-4421, doi:10.1175/JCLI-D-20-0882.1.
(53)Zhen Z., Y. Guo, and Z. Wen*, 2021: Inter-decadal change in the relationship between the Bay of Bengal summer monsoon and South China Sea summer monsoon onset. Front. Earth Sci., doi:0.3389/feart.2020.610982.
(54)Wang Z., Z. Wen*, R. Chen, X. Li, and S. Huang, 2020: Interdecadal enhancement in the interannual variability of the summer monsoon meridional circulation over the South China Sea around the early 1990s. Climate Dynamics, 55, 2149–2164, doi:10.1007/s00382-020-05375-3.
(55)Lin Z., B. Dong, Z. Wen, 2020: The effects of anthropogenic greenhouse gases and aerosols on the inter-decadal change of the South China Sea summer monsoon in the late 20th Century. Climate Dynamics. 54, 3339–3354, doi:10.1007/s00382-020-05175-9.
(56)Chen, W., L. Wang, J. Feng, Z. P. Wen, T. J, Ma, X. Q. Yang, and C. H. 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, doi:10.1007/s00376-019-8230-y.
(57)Zhu X., Y. Guo, H. Zhang, X. Li, R. Chen and Z. Wen*, 2018: A southward withdrawal of the north edge of the East Asian summer monsoon around the early 1990s. Atmospheric and Oceanic Sciences. 11(2), 136-142, doi:10.1080/16742834.2018.1410058.
(58)Zhang H., Z. Wen*, and R. Wu, 2017: Inter-decadal changes in the East Asian summer monsoon and associations with sea surface temperature anomaly in the South Indian Ocean. Climate Dynamics, 48,1125-1139, doi:10.1007/s00382-016-3131-6.
(59)LIANG Jie-Yi, WEN Zhi-Ping*, CHEN Jie-Peng and WU Li-Ji. 2013: Characteristics of Tropical Sea Surface Temperature Anomalies and Their Influences on the Onset of South China Sea Summer Monsoon. Atmospheric and Oceanic Sciences Letter. 6(5),266-272.
(60)Wu L., Z. Wen*, and R. Huang. 2020: Tropical cyclones in a warming climate. Science China Earth Science, 63(3): 456-458, doi:10.1007/s11430-019-9574-4.
(61)Chen, S., W. Li, Z. Wen, Y. Lu, M. Zhou, Y. Qian, and G. Chen, 2019: Vertical motions prior to the intensification of simulated Typhoon Hagupit (2008). Journal of Geophysical Research: Oceans, 124, 577–592, doi:10.1029/ 2018JC014086.
(62)Chen S., W. Li, Z. Wen, and Y. Qian, 2018: Variations in High-frequency Oscillations of Tropical Cyclones over the Western North Pacific. Advance in Atmospheric Sciences. 35 (4), 423-434, doi:10.1007/s00376-017-7060-z.
(63)Lin X., Z. Wen, W. Zhou, R. Wu, and R. Chen, 2017: Effect of Tropical Cyclone Activity on Boundary Moisture Budget of the East Asian Monsoon Region. Advances in Atmospheric Sciences, 34, 700-712, doi:10.1007/s00376-017- 6191-6.
(64)Chen J., Z. Wen*, and X. Wang, 2017: Relationship over southern China between the summer rainfall induced by tropical cyclones and that by monsoon. Atmos. Oceanic Sci. Lett., 10(1), 96-103, doi:10.1080/16742834.2017.1248756.
(65)Wu L., Z. Wen, and R. Wu, 2015: Influence the monsoon trough on westward-propagating synoptic-scale disturbances over the western North Pacific. Part I: Observations. Journal of Climate, 28(18), 7108-7127, doi:10.1175/JCLI-D-14-00806.1.
(66)Wu L., Z. Wen, and R. Wu, 2015: Influence the monsoon trough on westward-propagating synoptic-scale disturbances over the western North Pacific. Part II: Energetics and numerical experiments. Journal of Climate, 28, 9332-9349, doi:10.1175/JCLI-D-14-00807.1.
(67)Chen S., Y. Lu, W. Li, and Z. Wen, 2015: Identification and Analysis of High-Frequency Oscillations in the Eyewalls of Tropical Cyclones. Advances in Atmospheric Sciences,32, 624–634,doi:10.1007/s00376-014-4070-y.
(68)Chen S., W. Li, Y. Lu, and Z. Wen, 2014: Variations of latent heat flux during tropical cyclones over the South China Sea. Meteorol. Appl., 21: 717–723,doi:10.1002/met.1398.
(69)Wu L., Z. Wen*, T. Li, and R. Huang, 2014: ENSO-phase dependent TD and MRG wave activity in the western North Pacific. Climatic Dynamics, 42(5), 1217–1227, doi:10.1007/s00382-013-1754-4.
(70)Chen J., R. Wu, and Z. Wen, 2012: Contribution of South China Sea tropical cyclones to southern China summer rainfall increase around 1993. Advance in Atmospheric Sciences, 29(3), 585-598, doi:10.1007/s00376-011-1181-6.
(71)Wu L., Z. Wen*, R. Huang, and R Wu, 2012: Possible linkage between the monsoon trough variability and the tropical cyclone activity over the western North Pacific. Monthly Weather Review, 140(1), 140-150, doi:10.1175/MWR-D-11-00078.
(72)Guo Y., R. Zhang, Z. Wen*, J. Li, C. Zhang, and Z. Zhou, 2021: Understanding the role of SST anomaly in extreme rainfall of 2020 Meiyu Season from an interdecadal perspective. Science China Earth Sciences, 10(64), 1619-1632, doi:10.1007/s11430-020-9762-0.
(73)Chen X., A. Dai, Z. Wen, and Y. Song, 2021: Contributions of Arctic sea-ice loss and East Siberian atmospheric blocking to 2020 record-breaking Meiyu-Baiu rainfall. Geophysical Research Letters, 48, e2021GL092748, doi:10.1029/2021GL092748.
(74)Liu W., R. Chen,and Z. Wen, 2021: An interdecadal decrease of extreme heat days in August over Northeast China around the early 1990s. Atmospheric and Oceanic Science Letters, 14 (2021) 100001, doi:10.1016/j.aosl.2020.100001.
(75)Lin W., R. Chen, Z. Wen, and W. Chen, 2021: Large-scale circulation features associated with different types of extreme high temperatures over South China. International Journal of Climatology, doi:10.1002/joc.7283.
(76)Wu N., X. Ding, Z. Wen*, Z. Meng, G. Chen, and J. Min, 2020: Contrasting the frontal and warm-sector heavy rainfalls over South China during the early-summer rainy season, Atmospheric Research, 235, 104693, doi:10.1016/j.atmosres.
(77)Zeng, W., G. Chen, Y. Du, and Z. Wen, 2019: Diurnal variations of low-level winds and rainfall response to large-scale circulations during a heavy rainfall event. Monthly Weather Review, 147:3981-4004. doi:10.1175/MWR-D-19-0131.1.
(78)Chen R., Z. Wen, and R. Lu, 2019: Influences of tropical circulation and sea surface temperature anomalies on extreme heat over Northeast Asia in the midsummer of 2018. Atmospheric and Oceanic Science Letters, 12(4), 238-245, doi:0.1080/16742834.2019.1611170
(79)Chen R., Z. Wen, R. Lu and C. Wang, 2019: Causes of the Extreme Hot Midsummer in Central and South China during 2017: Role of the western tropical Pacific warming. Advance in Atmospheric Sciences. 36(5), 465-478, doi:10.1007/s00376-018-8177-4.
(80)Li J., D. Huang, F. Li, and Z. Wen, 2018: Circulation Characteristics of EP and CP ENSO and Their Impacts on Precipitation in South China. Journal of Atmospheric and Solar-Terrestrial Physics, 179, 405–415, doi:10.1016/j.jastp.2018.09.006.
(81)Chen, R., Z. Wen, and R. Lu, 2018: Interdecadal change on the relationship between the mid-summer temperature in South China and atmospheric circulation and sea surface temperature. Climate Dynamics. 51: 2113-2126, doi:10.1007/s00382-017-4002-5.
(82)Chen R., Z. Wen, and R. Lu, 2018: Large-scale circulation anomalies and intra-seasonal oscillations associated with the long-lived extreme heat events in South China. Journal of Climate. 31, 213-231. doi:10.1175/JCLI-D-17-0232.1.
(83)Chen, G., W. Sha, T. Iwasaki, and Z. Wen, 2017: Diurnal cycle of a heavy rainfall corridor over East Asia. Monthly Weather Review, 145 (8), 3365–3389, doi:10.1175/MWR-D-16-0423.1.
(84)Chen R., Z. Wen, R. Lu, 2016: Evolutions of the circulation anomalies and the quasi-biweekly oscillations associated with extreme heat events in South China. Journal of Climate, 29, 6909-6921, doi:10.1175/JCLI-D-16-0160.1.
(85)WU Li-Ji, WEN Zhi-Ping*, HE Hai-Yan, 2015: Relationship between the Periodic Fluctuations of Pressure and Precipitation during a Rainstorm. Atmos. Oceanic Sci. Lett., 8(2), 78-81, doi:10.3878/AOSL20140082.
(86)Wu Liji, Huang Ronghui, He Haiyan,, Shao Yaping and Wen Zhiping, 2010: Synoptic characteristics of heavy rainfall events in pre-monsoon season in South China. Adv. Atmos. Sci., 27(2), 315-327, doi:10.1007/s00376-009-8129-z.
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