{"id":131,"date":"2024-03-27T10:44:48","date_gmt":"2024-03-27T02:44:48","guid":{"rendered":"http:\/\/121.41.36.37\/?page_id=131"},"modified":"2025-06-11T22:08:16","modified_gmt":"2025-06-11T14:08:16","slug":"publications","status":"publish","type":"page","link":"http:\/\/www.wenzhou-clim.com\/zh\/publications","title":{"rendered":"\u8bba\u6587"},"content":{"rendered":"<div data-elementor-type=\"wp-page\" data-elementor-id=\"131\" class=\"elementor elementor-131\">\n\t\t\t\t<div class=\"elementor-element elementor-element-020ebcc e-flex e-con-boxed e-con e-parent\" data-id=\"020ebcc\" data-element_type=\"container\" data-core-v316-plus=\"true\">\n\t\t\t\t\t<div class=\"e-con-inner\">\n\t\t\t\t<div class=\"elementor-element elementor-element-1f4ddbf elementor-widget elementor-widget-text-editor\" data-id=\"1f4ddbf\" data-element_type=\"widget\" data-widget_type=\"text-editor.default\">\n\t\t\t\t<div class=\"elementor-widget-container\">\n\t\t\t<style>\/*! elementor - v3.20.0 - 10-04-2024 *\/\n.elementor-widget-text-editor.elementor-drop-cap-view-stacked .elementor-drop-cap{background-color:#69727d;color:#fff}.elementor-widget-text-editor.elementor-drop-cap-view-framed .elementor-drop-cap{color:#69727d;border:3px solid;background-color:transparent}.elementor-widget-text-editor:not(.elementor-drop-cap-view-default) .elementor-drop-cap{margin-top:8px}.elementor-widget-text-editor:not(.elementor-drop-cap-view-default) .elementor-drop-cap-letter{width:1em;height:1em}.elementor-widget-text-editor .elementor-drop-cap{float:left;text-align:center;line-height:1;font-size:50px}.elementor-widget-text-editor .elementor-drop-cap-letter{display:inline-block}<\/style>\t\t\t\t<p>Latest Update: 8 June 2025<\/p>\t\t\t\t\t\t<\/div>\n\t\t\t\t<\/div>\n\t\t\t\t<div class=\"elementor-element elementor-element-6adeb4d elementor-tabs-view-horizontal elementor-invisible elementor-widget elementor-widget-tabs\" data-id=\"6adeb4d\" data-element_type=\"widget\" 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.elementor-tabs-wrapper{justify-content:center}.elementor-widget-tabs.elementor-tabs-alignment-end .elementor-tabs-wrapper{justify-content:flex-end}.elementor-widget-tabs.elementor-tabs-alignment-stretch.elementor-tabs-view-horizontal .elementor-tab-title{width:100%}.elementor-widget-tabs.elementor-tabs-alignment-stretch.elementor-tabs-view-vertical .elementor-tab-title{height:100%}.elementor-tabs .elementor-tab-mobile-title{display:none}}<\/style>\t\t<div class=\"elementor-tabs\">\n\t\t\t<div class=\"elementor-tabs-wrapper\" role=\"tablist\" >\n\t\t\t\t\t\t\t\t\t<div id=\"elementor-tab-title-1121\" class=\"elementor-tab-title elementor-tab-desktop-title\" aria-selected=\"true\" data-tab=\"1\" role=\"tab\" tabindex=\"0\" aria-controls=\"elementor-tab-content-1121\" aria-expanded=\"false\">ALL<\/div>\n\t\t\t\t\t\t\t\t\t<div id=\"elementor-tab-title-1122\" class=\"elementor-tab-title elementor-tab-desktop-title\" aria-selected=\"false\" data-tab=\"2\" role=\"tab\" tabindex=\"-1\" aria-controls=\"elementor-tab-content-1122\" aria-expanded=\"false\">2025-2021<\/div>\n\t\t\t\t\t\t\t\t\t<div id=\"elementor-tab-title-1123\" class=\"elementor-tab-title elementor-tab-desktop-title\" aria-selected=\"false\" data-tab=\"3\" role=\"tab\" tabindex=\"-1\" aria-controls=\"elementor-tab-content-1123\" aria-expanded=\"false\">2020-2016<\/div>\n\t\t\t\t\t\t\t\t\t<div id=\"elementor-tab-title-1124\" class=\"elementor-tab-title elementor-tab-desktop-title\" aria-selected=\"false\" data-tab=\"4\" role=\"tab\" tabindex=\"-1\" aria-controls=\"elementor-tab-content-1124\" aria-expanded=\"false\">2015-2011<\/div>\n\t\t\t\t\t\t\t\t\t<div id=\"elementor-tab-title-1125\" class=\"elementor-tab-title elementor-tab-desktop-title\" aria-selected=\"false\" data-tab=\"5\" role=\"tab\" tabindex=\"-1\" aria-controls=\"elementor-tab-content-1125\" aria-expanded=\"false\">Before 2010<\/div>\n\t\t\t\t\t\t\t<\/div>\n\t\t\t<div class=\"elementor-tabs-content-wrapper\" role=\"tablist\" aria-orientation=\"vertical\">\n\t\t\t\t\t\t\t\t\t<div class=\"elementor-tab-title elementor-tab-mobile-title\" aria-selected=\"true\" data-tab=\"1\" role=\"tab\" tabindex=\"0\" aria-controls=\"elementor-tab-content-1121\" aria-expanded=\"false\">ALL<\/div>\n\t\t\t\t\t<div id=\"elementor-tab-content-1121\" class=\"elementor-tab-content elementor-clearfix\" data-tab=\"1\" role=\"tabpanel\" aria-labelledby=\"elementor-tab-title-1121\" tabindex=\"0\" hidden=\"false\"><h3>2025 \u00a0<\/h3><div><div><div><p>Zheng-Hang Fu, Dazhi Xi, Shang-Ping Xie, <strong>Wen Zhou*<\/strong>, Ning Lin, Jiuwei Zhao, Xin Wang, and Johnny C. L. Chan, 2025: Shifting hotspot of tropical cyclone clusters in a warming climate, Nature Climate Change, 15, accepted. <a href=\"http:\/\/www.wenzhou-clim.com\/wp-content\/uploads\/2025\/06\/FuXi2025_TCChotspot_main_submit.pdf\">[PDF]<\/a><\/p><p>Widana A. E. Lakshani, <strong>Wen Zhou*<\/strong>, Johnny C. L. Chan, Xuan Wang, Jayarathana W. N. D. Sandaruwan, and Zekai Ni, 2025: Linkages between the Indian Ocean Basin Mode and tropical cyclone activity in the North Indian and Western North Pacific Oceans. Climate Dynamics, 63, 171. <a href=\"https:\/\/doi.org\/10.1007\/s00382-025-07637-4\">[Link to Paper]<\/a><\/p><p>Bo Tong, <strong>Wen Zhou*<\/strong>, and Xin Wang*, 2025: Rising warm positive Indian Ocean dipole under global warming: Early western Indian Ocean warming as a key predictor. One Earth, 8. <a href=\"https:\/\/doi.org\/10.1016\/j.oneear.2025.101277\">[Link to Paper]<\/a><\/p><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Ye Tian, <strong>Wen Zhou*<\/strong>, Paxson K. Y. Cheung, and Zhenchen Liu, 2025: Vision Transformer for Extracting Tropical Cyclone Intensity from Satellite Images. <i>Advances in Atmospheric Sciences<\/i>, 42, 79-93. <a href=\"https:\/\/doi.org\/10.1007\/s00376-024-3191-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><\/div><p><span lang=\"EN-US\">Zhuoying Li, and <strong>Wen Zhou*<\/strong>, 2025: Westward shift of western North Pacific tropical cyclones in CMIP6-HighResMIP models. <i>Atmospheric and Oceanic Science Letters<\/i>, 100594. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283425000066\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p><span lang=\"EN-US\">Ruhua Zhang, <strong>Wen Zhou*<\/strong>, and Wenshou Tian, 2025: Holton-Tan effect enhances the influence of the QBO on the surface air temperature around the North Pacific. <i>Climate Dynamics<\/i>, 63, 128. <a href=\"https:\/\/doi.org\/10.1007\/s00382-024-07480-z\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Ruhua Zhang, <strong>Wen Zhou*<\/strong>, Yue Zhang, and Xiran Xu, 2025: Modulation of the Quasi-Biennial Oscillation on the East Asian Surface Air Temperature in Boreal Winter. <i>Journal of Climate<\/i>, 38, 87-99. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/38\/1\/JCLI-D-24-0207.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p><span lang=\"EN-US\">Lili Lei, Jianfang Fei, and <strong>\u5468\u6587<\/strong>, 2025: Theory and prediction of tropical cyclones and induced precipitation. <i>Atmospheric and Oceanic Science Letters<\/i>, 18, 100608. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283425000200\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p>Weiwei Zhang, Dongxiao Wang, Marco Y. T. Leung*, Lin Wang, Jinchi Xie, and <strong>\u5468\u6587<\/strong>, 2025: Upper-ocean cooling rate of the South China Sea in response to extreme cold surges and weak cold-air invasions. Atmospheric and Oceanic Science Letters, 18, 100517. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283424000667\">[Link to Paper]<\/a><\/p><p>Lixia Pan, Jiepeng Chen*, Xin Wang*, Haigang Zhan, <strong>\u5468\u6587<\/strong>, and Johnny C. L. Chan, 2025: More autumn tropical cyclone genesis in the South China Sea during El Ni\u00f1o to La Ni\u00f1a transition. npj Climate and Atmospheric Science, 8, 55. <a href=\"https:\/\/doi.org\/10.1038\/s41612-025-00947-8\">[Link to Paper]<\/a><\/p><\/div><div>\u00a0<\/div><h3>2024 \u00a0<\/h3><p>Zheng-Hang Fu, <strong>Wen Zhou*<\/strong>, Shang-Ping Xie*, Ruhua Zhang, and Xudong Wang, 2024: Dynamic pathway linking Pakistan flooding to East Asian heatwaves. <em>Science Advances<\/em>, 10, eadk9250. <a href=\"https:\/\/doi.org\/10.1126\/sciadv.adk9250\">[\u8bba\u6587\u4e3b\u9875]<\/a> <a href=\"https:\/\/www.science.org\/toc\/sciadv\/10\/17\">[Magazine cover]<\/a><\/p><p>Ruhua Zhang, <strong>Wen Zhou*<\/strong>, Wenshou Tian, Yue Zhang, Junxia Zhang, and Jiali Luo, 2024: A stratospheric precursor of East Asian summer droughts and floods. <em>Nature Communications<\/em>, 15, 247. <a href=\"https:\/\/doi.org\/10.1038\/s41467-023-44445-y\" target=\"_blank\" rel=\"noopener\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><span lang=\"EN-US\">Shifei Tu, Zhenzhen Hu, Mei Liang, <strong>Wen Zhou*<\/strong>, Johnny C. L. Chan, and Jianjun Xu*, 2024: Decreasing trend in destructive potential of tropical cyclones in the South Indian Ocean since the mid-1990s. <i>Communications Earth &amp; Environment<\/i>, 5, 543.<a href=\"https:\/\/doi.org\/10.1038\/s43247-024-01683-2\"> [\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Zhuoying Li, and <strong>Wen Zhou*<\/strong>, 2024: Poleward migration of tropical cyclones over the western North Pacific in the CMIP6-HighResMIP models constrained by observations. <i>npj Climate and Atmospheric Science<\/i>, 7, 161. <a href=\"https:\/\/doi.org\/10.1038\/s41612-024-00704-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Hongjie Liang, and <strong>Wen Zhou*<\/strong>, 2024: Dynamic and thermodynamic processes related to sea-ice surface melt advance in the Laptev Sea and East Siberian Sea. <i>The Cryosphere<\/i>, 18, 3559-3569. <a href=\"https:\/\/tc.copernicus.org\/articles\/18\/3559\/2024\/\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Zhenchen Liu, <strong>Wen Zhou*<\/strong>, and Xin Wang, 2024: Extreme Meteorological Drought Events over China (1951\u20132022): Migration Patterns, Diversity of Temperature Extremes, and Decadal Variations. <i>Advances in Atmospheric Sciences<\/i>. <a href=\"https:\/\/doi.org\/10.1007\/s00376-024-4004-2\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><\/div><\/div><p>Xiuzhen Li*, Zhiping Wen, and <strong>\u5468\u6587<\/strong>, 2024: Different configurations of the Eurasian pattern and South Asian jet wave train and their impacts on the winter climate over East Asia. <em>Climate Dynamics<\/em>. <a href=\"https:\/\/doi.org\/10.1007\/s00382-024-07176-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><div><div><span lang=\"EN-US\">Xiaoli Zhou, <strong>Wen Zhou*<\/strong>, Dongxiao Wang, Qiang Xie, Lei Yang*, and Qihua Peng, 2024: Westerlies Affecting the Seasonal Variation of Water Vapor Transport over the Tibetan Plateau Induced by Tropical Cyclones in the Bay of Bengal. <i>Advances in Atmospheric Sciences<\/i>, 41, 881-893. <a href=\"https:\/\/doi.org\/10.1007\/s00376-023-3093-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/div><div>\u00a0<\/div><\/div><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Chao He*, Xiaolong Chen, Matthew Collins, Fengfei Song, Yamin Hu, Xingwen Jiang, Yanju Liu, Yihui Ding, and <strong>\u5468\u6587<\/strong>, 2024: Rising geopotential height under global warming. <i>Climate Dynamics<\/i>. <a href=\"https:\/\/doi.org\/10.1007\/s00382-024-07175-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Xiaocheng Yu, Yue Zhang*, and <strong>\u5468\u6587<\/strong>, 2024: Distinct preceding oceanic drivers for interannual variation of summer tropical cyclone\u2013induced rainfall in South and East China. <i>Climate Dynamics<\/i>. <a href=\"https:\/\/doi.org\/10.1007\/s00382-024-07206-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><p>Jiasi Chen, Yuanhong Guan*, <strong>Wen Zhou,<\/strong> Xianghua Wu, Qifeng Lu, and Xingyu Li, 2024: Influence of the Southern Indian Ocean Dipole on the following spring climate in China: A synthetic observational and numerical study. <em>Atmospheric Research<\/em>, 299, 107183. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S016980952300580X\" target=\"_blank\" rel=\"noopener\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiaorui Zhang, Xiao Lu*, Fan Wang, <strong>Wen Zhou,<\/strong> Peng Wang, and Meng Gao*, 2024: Enhanced Late Spring Ozone in Southern China by Early Onset of the South China Sea Summer Monsoon. <em>Journal of Geophysical Research: Atmospheres<\/em>, 129, e2023JD039029. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2023JD039029\" target=\"_blank\" rel=\"noopener\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Oluwafemi E. Adeyeri, <strong>Wen Zhou*<\/strong>, Christopher E. Ndehedehe, and Xuan Wang, 2024: Global vegetation, moisture, thermal and climate interactions intensify compound extreme events. <em>Science of the Total Environment<\/em>, 912, 169261. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0048969723078919\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><div><p><span lang=\"EN-US\">Yue Zhang, <strong>Wen Zhou*<\/strong>, and Ruhua Zhang, 2024: Decadal Changes in Dry and Wet Heatwaves in Eastern China: Spatial Patterns and Risk Assessment. <i>Advances in Atmospheric Sciences<\/i>, 41, 2011-2026. <a href=\"https:\/\/doi.org\/10.1007\/s00376-024-3261-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p>Yue Zhang, <strong>Wen Zhou*<\/strong>, Xiaocheng Yu, Ye Tian, and Ruhua Zhang, 2024: Long-term coupled variability of temperature and precipitation in eastern China and the underlying mechanisms. <em>Climate Dynamics<\/em>, 62, 1447-1465. <a href=\"https:\/\/doi.org\/10.1007\/s00382-023-06963-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><\/div><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Xuan Tong, and <strong>Wen Zhou*<\/strong>, 2024: Assessing predictive attribution in NMME forecasts of summer precipitation in eastern china using deep learning. <i>npj Climate and Atmospheric Science<\/i>, 7, 304.<a href=\"https:\/\/doi.org\/10.1038\/s41612-024-00835-7\"> [\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><p>Xuan Tong, <strong>Wen Zhou*<\/strong>, and Jiangjiang Xia, 2024: Improving Boreal Summer Precipitation Predictions From the Global NMME Through Res34-Unet. <em>Geophysical Research Letters<\/em>, 51, e2023GL106391. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2023GL106391\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Oluwafemi E. Adeyeri*, <strong>Wen Zhou*,<\/strong> Christopher E. Ndehedehe, Xuan Wang, Kazeem A. Ishola, and Patrick Laux, 2024: Minimizing uncertainties in climate projections and water budget reveals the vulnerability of freshwater to climate change. <em>One Earth<\/em>, 7, 72-87. <a href=\"https:\/\/doi.org\/10.1016\/j.oneear.2023.12.013\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang, and <strong>Wen Zhou*<\/strong>, 2024: Influence of Internal Climate System Forcing on the Relationship Between North Atlantic Tropical Cyclones and Saharan Dust. <em>Journal of Geophysical Research: Atmospheres<\/em>, 129, e2023JD039766. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2023JD039766\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, and <strong>Wen Zhou*<\/strong>, 2024: Interdecadal variation of the monsoon trough and its relationship with tropical cyclone genesis over the South China Sea and Philippine Sea around the mid-2000s. <em>Climate Dynamics<\/em>. <a href=\"https:\/\/doi.org\/10.1007\/s00382-023-07096-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>Wen Zhou*,<\/strong> Jinxiao Li, Zixiang Yan, Zili Shen, Bo Wu, Bin Wang, Ronghua Zhang, and Zhijin Li*, 2024: Progress and future prospects of decadal prediction and data assimilation: A review. <em>Atmospheric and Oceanic Science Letters<\/em>, 17, 100441. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S167428342300140X\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>M. Pear Hossain, <strong>\u5468\u6587<\/strong>, Marco Y. T. Leung, and Hsiang-Yu Yuan*, 2024: Association of air pollution and weather conditions during infection course with COVID-19 case fatality rate in the United Kingdom. <em>Scientific reports<\/em>, 14, 683. <a href=\"https:\/\/doi.org\/10.1038\/s41598-023-50474-w\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuqing Wang, <strong>Wen Zhou*<\/strong>, and Chunzai Wang*, 2024: Physical mechanism of the rapid increase in intense and long-lived extreme heatwaves in the Northern Hemisphere since 1980.<em> Science China Earth Sciences<\/em>. <a href=\"https:\/\/doi.org\/10.1007\/s11430-023-1332-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Shuai-Lei Yao*, Renguang Wu*, Jing-Jia Luo, and <strong>\u5468\u6587<\/strong>, 2024: Competing impacts of tropical Pacific and Atlantic on Southern Ocean inter-decadal variability. <em>npj Climate and Atmospheric Science<\/em>, 7, 104. <a href=\"https:\/\/doi.org\/10.1038\/s41612-024-00662-w\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwei Zhang, Dongxiao Wang, Marco Y. T. Leung*, Lin Wang, Jinchi Xie, and <strong>\u5468\u6587<\/strong>, 2024: Upper-ocean cooling rate of the South China Sea in response to extreme cold surges and weak cold-air invasions. <em>Atmospheric and Oceanic Science Letters<\/em>, 100517. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283424000667\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Zixiang Yan, <strong>Wen Zhou*<\/strong>, Jinxiao Li, Xuedan Zhu, Yuxin Zang, and Liuyi Zhang, 2024: Skillful Seasonal Prediction of Global Onshore Wind Resources in SIDRI-ESS V1.0. <i>Sustainability<\/i>, 16, 7721. <a href=\"https:\/\/www.mdpi.com\/2071-1050\/16\/17\/7721\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p><span lang=\"EN-US\">Zixiang Yan, Jinxiao Li*, <strong>\u5468\u6587<\/strong>, Zouxing Lin, Yuxin Zang, and Siyuan Li, 2024: Evaluation of Seasonal Prediction of Extreme Wind Resource Potential over China Based on a Dynamic Prediction System SIDRI-ESS V1.0. <i>Atmosphere<\/i>, 15, 1024. <a href=\"https:\/\/www.mdpi.com\/2073-4433\/15\/9\/1024\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><h3>\u00a0<\/h3><h3>2023<\/h3><p>Zhenchen Liu, and <strong>Wen Zhou*<\/strong>, 2023: Glo3DHydroClimEventSet(v1.0): A global-scale event set of hydroclimatic extremes detected with the 3D DBSCAN-based workflow (1951\u20132022). <em>International Journal of Climatology<\/em>, 43, 7722-7744. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/joc.8289\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zili Shen, <strong>Wen Zhou*<\/strong>, Jinxiao Li, and Johnny C. 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Adeyeri*, <strong>Wen Zhou*<\/strong>, Patrick Laux, Xuan Wang, Diarra Dieng, Lakshani A. E. Widana, and Muhammad Usman, 2023: Land use and land cover dynamics: Implications for thermal stress and energy demands. <em>Renewable and Sustainable Energy Reviews<\/em>, 179, 113274. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1364032123001302\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuntao Jian, Marco Y. T. Leung, Ruhua Zhang, <strong>\u5468\u6587<\/strong>, Maoqiu Jian, Song Yang, Yerong Feng, and Banglin Zhang*, 2023: Bias and Uncertainty of the Relationship between AO and Winter Synoptic Temperature Variability over the Northern Hemisphere under Present and Future Climate. <em>Journal of Climate<\/em>, 36, 3245-3259. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/36\/10\/JCLI-D-22-0230.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jayarathna W. N. D. Sandaruwan, <strong>Wen Zhou*<\/strong>, Paxson K. Y. 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Cheung, 2022: Changes in the Relationship between ENSO and the Winter Arctic Stratospheric Polar Vortex in Recent Decades. <em>Journal of Climate<\/em>, 35, 5399-5414. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/35\/16\/JCLI-D-21-0924.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiaocheng Yu, <strong>Wen Zhou*<\/strong>, and Yue Zhang, 2022: The decadal shift in TC-induced precipitation over China. <em>Atmospheric Research<\/em>, 274, 106186. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0169809522001727\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ho-Nam Cheung*, Noel Keenlyside, Torben Koenigk, Shuting Yang, Tian Tian, Zhiqing Xu, Yongqi Gao, Fumiaki Ogawa, Nour-Eddine Omrani, Shaobo Qiao, and <strong>Wen Zhou*<\/strong>, 2022: Assessing the influence of sea surface temperature and arctic sea ice cover on the uncertainty in the boreal winter future climate projections. <em>Climate Dynamics<\/em>, 59, 433-454. <a href=\"https:\/\/doi.org\/10.1007\/s00382-022-06136-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y.-T. Leung, Dongxiao Wang, <strong>Wen Zhou*<\/strong>, Yue Zhang, and Lin Wang, 2022: Interdecadal Variation in Available Potential Energy of Stationary Eddies in the Midlatitude Northern Hemisphere in Response to the North Pacific Gyre Oscillation. <em>Geophysical Research Letters<\/em>, 49, e2022GL098297. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2022GL098297\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p style=\"font-weight: 400;\">Yue Zhang, <strong>Wen Zhou*<\/strong>, Xin Wang, Sheng Chen, Jiepeng Chen, and Shanshan Li, 2022: Indian Ocean Dipole and ENSO\u2019s mechanistic importance in modulating the ensuing-summer precipitation over Eastern China. <em><i>npj Climate and Atmospheric Science<\/i><\/em>, 5, 48.\u00a0<a href=\"https:\/\/doi.org\/10.1038\/s41612-022-00271-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, Dongxiao Wang, <strong>Wen Zhou*<\/strong>, Paxson K. Y. Cheung, Yuntao Jian, and Fuan Xiao, 2022: Joint Effect of West Pacific Warming and the Arctic Oscillation on the Bidecadal Variation and Trend of the East Asian Trough. <em>Journal of Climate<\/em>, 35, 2491-2501. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/35\/8\/JCLI-D-21-0461.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Chong-wei Zheng*, Di Wu, Hai-lang Wu, Jing Guo, Chong Shen, Chuan Tian, Xin-long Tian, Zi-niu Xiao, <strong>\u5468\u6587<\/strong>, and Chong-yin Li, 2022: Propagation and attenuation of swell energy in the Pacific Ocean. <em>Renewable Energy<\/em>, 188, 750-764. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0960148122002130\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>E. Adeyeri*, P. Laux, K. A. Ishola, <strong>\u5468\u6587<\/strong>, I. A. Balogun, Z. D. Adeyewa, and H. 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E. Lakshani, <strong>Wen Zhou*<\/strong>, and Paxson K. Y. Cheung, 2022: Impacts of El Ni\u00f1o Diversity on Tropical Cyclone Activity in the Bay of Bengal. <em>Frontiers in Earth Science<\/em>, 10. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/feart.2022.824769\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ye Tian, <strong>Wen Zhou*<\/strong>, and W. K. Wong, 2022: Detecting Interdecadal Change in Western North Pacific Tropical Cyclone Genesis Based on Cluster Analysis Using pHash + Kmeans. <em>Frontiers in Earth Science<\/em>, 9. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/feart.2021.825835\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Paxson K. Y. Cheung, <strong>Wen Zhou*<\/strong>, Dongxiao Wang, and Marco Y. T. Leung, 2022: Dissimilarity among Ocean Reanalyses in Equatorial Pacific Upper-Ocean Heat Content and Its Relationship with ENSO. <em>Advances in Atmospheric Sciences<\/em>, 39, 67-79. <a href=\"https:\/\/doi.org\/10.1007\/s00376-021-1109-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2021<\/h3><p>Yuntao Jian, Marco Y. T. Leung, <strong>Wen Zhou*<\/strong>, Maoqiu Jian, and Song Yang, 2021: Present and Future Relations between ENSO and Winter Synoptic Temperature Variability over the Asian\u2013Pacific\u2013American Region Simulated by CMIP5\/6. <em>Journal of Climate<\/em>, 34, 9899-9913. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/34\/24\/JCLI-D-21-0210.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Shuai-Lei Yao*, <strong>Wen Zhou*<\/strong>, Fei-Fei Jin, and Fei Zheng, 2021: North Atlantic as a Trigger for Pacific-Wide Decadal Climate Change. <em>Geophysical Research Letters<\/em>, 48, e2021GL094719. <a href=\"https:\/\/doi.org\/10.1029\/2021GL094719\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenchen Liu, and <strong>Wen Zhou*<\/strong>, 2021: The 2019 Autumn Hot Drought Over the Middle-Lower Reaches of the Yangtze River in China: Early Propagation, Process Evolution, and Concurrence. <em>Journal of Geophysical Research: Atmospheres<\/em>, 126, e2020JD033742. <a href=\"https:\/\/doi.org\/10.1029\/2020JD033742\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Paxson K. Y. Cheung, Marco Y. T. Leung, and <strong>Wen Zhou*<\/strong>, 2021: Position, Magnitude, and Size of Warm-Pool El Ni\u00f1o: Variability, Seasonal Predictability, and Climate Impacts. <em>Journal of Geophysical Research: Atmospheres<\/em>, 126, e2021JD034917. <a href=\"https:\/\/doi.org\/10.1029\/2021JD034917\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuntao Jian, Marco Y. T. Leung, <strong>Wen Zhou*<\/strong>, Maoqiu Jian, Song Yang, and Xiaoxia Lin, 2021: Interdecadal Shift of the Relationship between ENSO and Winter Synoptic Temperature Variability over the Asian\u2013Pacific\u2013American Region in the 1980s. <em>Journal of Climate<\/em>, 34, 5321-5335. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/34\/13\/JCLI-D-20-0931.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Gang Li, <strong>Wen Zhou*<\/strong>, Yue Zhang, and Hongming Yan, 2021: Spatiotemporal characteristics of spring rainfall over Southwest China and their relationships with sea surface temperature during 1961\u20132017. <em>Theoretical and Applied Climatology<\/em>, 145, 775-786. <a href=\"https:\/\/doi.org\/10.1007\/s00704-021-03648-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiaochi Huang, Han Zhou, Xiaofeng Yang, <strong>Wen Zhou*<\/strong>, Jiejun Huang, and Yanbin Yuan, 2021: Spatial Characteristics of Coronavirus Disease 2019 and Their Possible Relationship With Environmental and Meteorological Factors in Hubei Province, China. <em>GeoHealth<\/em>, 5, e2020GH000358. <a href=\"https:\/\/doi.org\/10.1029\/2020GH000358\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang*, Bingyin Chen, Yong Xu, <strong>\u5468\u6587<\/strong>, and Xuemei Wang, 2021: Urban heat islands in Hong Kong: Bonding with atmospheric stability. <em>Atmospheric Science Letters<\/em>, 22, e1032. <a href=\"https:\/\/doi.org\/10.1002\/asl.1032\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang*, and <strong>\u5468\u6587<\/strong>, 2021: Influence of dust aerosols on eastern Pacific tropical cyclone intensity. <em>Atmospheric and Oceanic Science Letters<\/em>, 14, 100028. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283420300283\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Han Zhou, Xiaochi Huang, <strong>Wen Zhou*<\/strong>, Yue Zhang, and Yong Liu, 2021: Spatial correlation length of summer extreme heat stress over eastern China. <em>International Journal of Climatology<\/em>, 41, 3121-3138. <a href=\"https:\/\/doi.org\/10.1002\/joc.7009\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yue Zhang, <strong>Wen Zhou*<\/strong>, and Tim Li, 2021: Impact of the Indian Ocean Dipole on Evolution of the Subsequent ENSO: Relative Roles of Dynamic and Thermodynamic Processes. <em>Journal of Climate<\/em>, 34, 3591-3607. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/34\/9\/JCLI-D-20-0487.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yana Li, Ho-Nam Cheung*, and <strong>\u5468\u6587<\/strong>, 2021: Asymmetric Relationship Between Mid-latitude Eurasian Circulation and Summer Rainfall in Hong Kong in Different Phases of ENSO. <em>Frontiers in Earth Science<\/em>, 9. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/feart.2021.642588\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2020<\/h3><p>Han Zhou, <strong>\u5468\u6587<\/strong>, Yuanbo Liu*, Yanbin Yuan, Jiejun Huang, and Yongwei Liu, 2020: Identifying spatial extent of meteorological droughts: An examination over a humid region. <em>Journal of Hydrology<\/em>, 591, 125505. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0022169420309653\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintomide Afolayan Akinsanola, <strong>Wen Zhou*<\/strong>, Tianjun Zhou, and Noel Keenlyside, 2020: Amplification of synoptic to annual variability of West African summer monsoon rainfall under global warming. <em>npj Climate and Atmospheric Science<\/em>, 3, 21. <a href=\"https:\/\/doi.org\/10.1038\/s41612-020-0125-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Chao He, and <strong>Wen Zhou*<\/strong>, 2020: Different Enhancement of the East Asian Summer Monsoon under Global Warming and Interglacial Epochs Simulated by CMIP6 Models: Role of the Subtropical High. <em>Journal of Climate<\/em>, 33, 9721-9733. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/22\/jcliD200304.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Chao He, Tim Li, and <strong>Wen Zhou*<\/strong>, 2020: Drier North American Monsoon in Contrast to Asian\u2013African Monsoon under Global Warming. <em>Journal of Climate<\/em>, 33, 9801-9816. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/22\/jcliD200189.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuntao Jian, Xiaoxia Lin, <strong>\u5468\u6587<\/strong>, Maoqiu Jian*, Marco Y. T. Leung, and Paxson K. Y. Cheung, 2020: Analysis of Record-High Temperature over Southeast Coastal China in Winter 2018\/19: The Combined Effect of Mid- to High-Latitude Circulation Systems and SST Forcing over the North Atlantic and Tropical Western Pacific. <em>Journal of Climate<\/em>, 33, 8813-8831. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/20\/jcliD190732.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, <strong>Wen Zhou*<\/strong>, Dongxiao Wang, P. W. Chan, S. M. Lee, and H. W. Tong, 2020: Remote Tropical Western Indian Ocean Forcing on Changes in June Precipitation in South China and the Indochina Peninsula. <em>Journal of Climate<\/em>, 33, 7553-7566. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/17\/jcliD190626.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yong Liu*, <strong>\u5468\u6587<\/strong>, Xia Qu, and Renguang Wu, 2020: An Interdecadal Change of the Boreal Summer Silk Road Pattern around the Late 1990s. <em>Journal of Climate<\/em>, 33, 7083-7100. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/16\/JCLI-D-19-0795.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>YaJun Shi, Yan Du*, Zesheng Chen, and <strong>\u5468\u6587<\/strong>, 2019: Occurrence and impacts of tropical cyclones over the southern South China Sea. <em>International Journal of Climatology<\/em>, 40, 4218 \u2013 4227.<a href=\"https:\/\/doi.org\/10.1002\/joc.6454\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo T. Abolude*, <strong>\u5468\u6587<\/strong>, and Akintomide A. Akinsanola, 2020: Evaluation and Projections of Wind Power Resources over China for the Energy Industry Using CMIP5 Models. <em>Energies<\/em>, 13, 2417. <a href=\"https:\/\/doi.org\/10.3390\/en13102417\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintomide A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2020: Understanding the Variability of West African Summer Monsoon Rainfall: Contrasting Tropospheric Features and Monsoon Index. <em>Atmosphere,<\/em> 11, 309. <a href=\"https:\/\/doi.org\/10.3390\/atmos11030309\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Shaobo Qiao, Meng Zou, Ho Nam Cheung*, <strong>\u5468\u6587<\/strong>, Qingxiang Li, Guolin Feng, and Wenjie Dong*, 2020: Predictability of the wintertime 500\u00a0hPa geopotential height over Ural-Siberia in the NCEP climate forecast system. <em>Climate Dynamics<\/em>, 54, 1591-1606. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-05074-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Han Zhou, <strong>\u5468\u6587<\/strong>, Yuanbo Liu*, Yanbin Yuan, Jiejun Huang, and Yongwei Liu, 2020: Meteorological Drought Migration in the Poyang Lake Basin, China: Switching among Different Climate Modes. <em>Journal of Hydrometeorology<\/em>, 21, 415-431. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/hydr\/21\/3\/jhm-d-19-0183.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2019<\/h3><p>Yue Zhang, <strong>Wen Zhou*<\/strong>, Eric C. H. Chow, and Marco Y. T. Leung, 2019: Delayed impacts of the IOD: cross-seasonal relationships between the IOD, Tibetan Plateau snow, and summer precipitation over the Yangtze\u2013Huaihe River region. <em>Climate Dynamics<\/em>, 53, 4077-4093. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-04774-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yana Li, Song Yang*, Yi Deng, Xiaoming Hu, Ming Cai, and <strong>\u5468\u6587<\/strong>, 2019: Detection and attribution of upper-tropospheric warming over the tropical western Pacific. <em>Climate Dynamics<\/em>, 53, 3057-3068. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-04681-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Fuan Xiao, Dongxiao Wang, Lili Zeng*, Qin-Yan Liu, and <strong>\u5468\u6587<\/strong>, 2019: Contrasting changes in the sea surface temperature and upper ocean heat content in the South China Sea during recent decades. <em>Climate Dynamics<\/em>, 53, 1597-1612. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-04697-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, <strong>Wen Zhou*<\/strong>, K. Y. Cheung, H. N. Gong, and Y. Zhang, 2019: Enhancement of lower tropospheric winter synoptic temperature variations in Southwest China and the northern Indochina Peninsula after 2010. <em>Climate Dynamics<\/em>, 53, 2281-2294. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-04841-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hainan Gong, Lin Wang*, Wen Chen, Renguang Wu, <strong>\u5468\u6587<\/strong>, Lin Liu, Debashis Nath, and Xiaoqing Lan, 2019: Diversity of the Wintertime Arctic Oscillation Pattern among CMIP5 Models: Role of the Stratospheric Polar Vortex. <em>Journal of Climate<\/em>, 32, 5235-5250. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/32\/16\/jcli-d-18-0603.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2019: Projection of West African summer monsoon rainfall in dynamically downscaled CMIP5 models. <em>Climate Dynamics<\/em>, 53, 81-95. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4568-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Eric C. H. Chow, Min Wen, Lei Li, Marco Y. T. Leung, Paxson K. Y. Cheung, and <strong>Wen Zhou*<\/strong>, 2019: Assessment of the Environmental and Societal Impacts of the Category-3 Typhoon Hato. <em>Atmosphere,<\/em> 10, 296. <a href=\"https:\/\/doi.org\/10.3390\/atmos10060296\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Wei Wei*, Yuting Wu, Song Yang, and <strong>\u5468\u6587<\/strong>, 2019: Role of the South Asian High in the Onset Process of the Asian Summer Monsoon during Spring-to-Summer Transition. <em>Atmosphere,<\/em> 10, 239. <a href=\"https:\/\/doi.org\/10.3390\/atmos10050239\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yue Zhang, <strong>Wen Zhou*<\/strong>, and Marco Y. T. Leung, 2019: Phase relationship between summer and winter monsoons over the South China Sea: Indian Ocean and ENSO forcing. <em>Climate Dynamics<\/em>, 52, 5229-5248. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4440-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2019: Ensemble-based CMIP5 simulations of West African summer monsoon rainfall: current climate and future changes. <em>Theoretical and Applied Climatology<\/em>, 136, 1021-1031. <a href=\"https:\/\/doi.org\/10.1007\/s00704-018-2516-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2019: Dynamic and thermodynamic factors controlling increasing summer monsoon rainfall over the West African Sahel. <em>Climate Dynamics<\/em>, 52, 4501-4514. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4394-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Shuang Qiu, and <strong>Wen Zhou*<\/strong>, 2019: Variation in Summer Rainfall over the Yangtze River Region during Warming and Hiatus Periods. <em>Atmosphere<\/em>, 10, 173. <a href=\"https:\/\/doi.org\/10.3390\/atmos10040173\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hainan Gong, <strong>Wen Zhou*<\/strong>, Wen Chen, Lin Wang, Marco Y. T. Leung, Paxson K. Y. Cheung, and Yue Zhang, 2019: Modulation of the southern Indian Ocean dipole on the impact of El Ni\u00f1o\u2013Southern Oscillation on Australian summer rainfall. <em>International Journal of Climatology<\/em>, 39, 2484-2490. <a href=\"https:\/\/doi.org\/10.1002\/joc.5941\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2019: Projections of West African summer monsoon rainfall extremes from two CORDEX models. <em>Climate Dynamics<\/em>, 52, 2017-2028. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4238-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang*, <strong>\u5468\u6587<\/strong>, and Liangui Yang, 2019: Analysis of dust wet deposition in the mid-latitudes of the Northern Hemisphere. <em>Air Quality, Atmosphere &amp; Health<\/em>, 12, 217-227. <a href=\"https:\/\/doi.org\/10.1007\/s11869-018-0652-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo T. Abolude, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2019: A Comparative Computational Fluid Dynamic Study on the Effects of Terrain Type on Hub-Height Wind Aerodynamic Properties. <em>Energies<\/em>, 12, 83. <a href=\"https:\/\/www.mdpi.com\/1996-1073\/12\/1\/83\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2018<\/h3><p>Marco Y. T. Leung, Shuang Qiu, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Modulations of rising motion and moisture on summer precipitation over the middle and lower reaches of the Yangtze river. <em>Climate Dynamics<\/em>, 51, 4259-4269. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4247-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hainan Gong, Lin Wang, <strong>\u5468\u6587<\/strong>, Wen Chen*, Renguang Wu, Lin Liu, Debashis Nath, and Marco Y. T. 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Chow, Richard C. Y. Li, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Influence of Tropical Cyclones on Hong Kong Air Quality. <em>Advances in Atmospheric Sciences<\/em>, 35, 1177-1188. <a href=\"https:\/\/doi.org\/10.1007\/s00376-018-7225-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jiepeng Chen, Xin Wang*, <strong>\u5468\u6587<\/strong>, and Zhiping Wen, 2018: Interdecadal change in the summer SST-precipitation relationship around the late 1990s over the South China Sea. <em>Climate Dynamics<\/em>, 51, 2229-2246. <a href=\"https:\/\/doi.org\/10.1007\/s00382-017-4009-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo Temiloluwa Abolude, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Assessment and Performance Evaluation of a Wind Turbine Power Output. <em>Energies<\/em>, 11, 1992. <a href=\"https:\/\/www.mdpi.com\/1996-1073\/11\/8\/1992\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Circumglobal teleconnection and eddy control of variation in summer precipitation over Northwest China. <em>Climate Dynamics<\/em>, 51, 1351-1362. <a href=\"https:\/\/doi.org\/10.1007\/s00382-017-3958-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Cheng Qian*, <strong>\u5468\u6587<\/strong>, Xiu-Qun Yang, and Johnny C. L. Chan, 2018: Statistical prediction of non-Gaussian climate extremes in urban areas based on the first-order difference method. <em>International Journal of Climatology<\/em>, 38, 2889-2898. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/joc.5464\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Chi-Ming Shun, and Pak-Wai Chan, 2018: Large-scale Circulation Control of the Occurrence of Low-level Turbulence at Hong Kong International Airport. <em>Advances in Atmospheric Sciences<\/em>, 35, 435-444. <a href=\"https:\/\/doi.org\/10.1007\/s00376-017-7118-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Revisiting the intraseasonal, interannual and interdecadal variability of tropical cyclones in the western North Pacific. <em>Atmospheric and Oceanic Science Letters<\/em>, 11, 198-208. <a href=\"https:\/\/doi.org\/10.1080\/16742834.2018.1459460\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung*, Noel Keenlyside, Nour-Eddine Omrani, and <strong>\u5468\u6587<\/strong>, 2018: Remarkable link between projected uncertainties of Arctic sea-ice decline and winter Eurasian climate. <em>Advances in Atmospheric Sciences<\/em>, 35, 38-51. <a href=\"https:\/\/doi.org\/10.1007\/s00376-017-7156-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Gang Li, Jiepeng Chen, Xin Wang*, Xia Luo, Daoyong Yang, <strong>\u5468\u6587<\/strong>, Yanke Tan, and Hongming Yan, 2018: Remote impact of North Atlantic sea surface temperature on rainfall in southwestern China during boreal spring. <em>Climate Dynamics<\/em>, 50, 541-553. <a href=\"https:\/\/doi.org\/10.1007\/s00382-017-3625-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Fuan Xiao, Lili Zeng, Qin-Yan Liu, <strong>\u5468\u6587<\/strong>, and Dongxiao Wang*, 2018: Extreme subsurface warm events in the South China Sea during 1998\/99 and 2006\/07: observations and mechanisms. <em>Climate Dynamics<\/em>, 50, 115-128. <a href=\"https:\/\/doi.org\/10.1007\/s00382-017-3588-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2017<\/h3><p>Shuang Qiu, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Marco Yu-Ting Leung, and Xiuzhen Li, 2017: Regional moisture budget associated with drought\/flood events over China. <em>Progress in Earth and Planetary Science<\/em>, 4, 36. <a href=\"https:\/\/doi.org\/10.1186\/s40645-017-0148-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo T. Abolude, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, and Yu Ting Leung, 2017: Regional Impact Assessment of Monsoon Variability on Wind Power Availability and Optimization in Asia. <em>Atmosphere<\/em>, 8, 219. <a href=\"https:\/\/www.mdpi.com\/2073-4433\/8\/11\/219\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2017: Impact of Arctic amplification on East Asian winter climate. <em>Atmospheric and Oceanic Science Letters<\/em>, 10, 385-388. <a href=\"https:\/\/doi.org\/10.1080\/16742834.2017.1350093\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiaobin Lin, Zhiping Wen, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Renguang Wu, and Ruidan Chen, 2017: Effects of tropical cyclone activity on the boundary moisture budget over the eastern China monsoon region. <em>Advances in Atmospheric Sciences<\/em>, 34, 700-712. <a href=\"https:\/\/doi.org\/10.1007\/s00376-017-6191-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, C. M. Shun, and Tsz Cheung Lee, 2017: Change in Destructiveness of Landfalling Tropical Cyclones over China in Recent Decades. <em>Journal of Climate<\/em>, 30, 3367-3379. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-16-0258.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang, <strong>\u5468\u6587<\/strong>, Mark Wenig, and Liangui Yang*, 2017: Impact of long-range desert dust transport on coastal East Asia: analysis of urban dust concentration and wet deposition with model simulation. <em>Air Quality, Atmosphere &amp; Health<\/em>, 10, 325-337. <a href=\"https:\/\/doi.org\/10.1007\/s11869-016-0440-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2017: Statistical modeling and trend detection of extreme sea level records in the Pearl River Estuary. <em>Advances in Atmospheric Sciences<\/em>, 34, 383-396. <a href=\"https:\/\/doi.org\/10.1007\/s00376-016-6041-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo Abolude*, and <strong>\u5468\u6587<\/strong>, 2017: A preliminary analysis of wind turbine energy yield. <em>Energy Procedia<\/em>, 138, 423-428. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1876610217351329\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, Yongqin David Chen*, and <strong>\u5468\u6587<\/strong>, 2017: Response of Winter Moisture Circulation to the India\u2013Burma Trough and Its Modulation by the South Asian Waveguide. <em>Journal of Climate<\/em>, 30, 1197-1210. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-16-0111.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang, <strong>\u5468\u6587<\/strong>, Mark Wenig, and Liangui Yang*, 2017: Impact of long-range desert dust transport on hydrometeor formation over coastal East Asia. <em>Advances in Atmospheric Sciences<\/em>, 34, 101-115. <a href=\"https:\/\/doi.org\/10.1007\/s00376-016-6157-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong><strong>*<\/strong>, Richard C. Y. Li, and Eric C. H. Chow, 2017: Intraseasonal variation of visibility in Hong Kong. <em>Advances in Atmospheric Sciences<\/em>, 34, 26-38. <a href=\"https:\/\/doi.org\/10.1007\/s00376-016-6056-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, Hoffman H. N. Cheung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2017: Meridional displacement of the East Asian trough and its response to the ENSO forcing. <em>Climate Dynamics<\/em>, 48, 335-352. <a href=\"https:\/\/doi.org\/10.1007\/s00382-016-3077-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2016<\/h3><p>Hoffman H. N. Cheung, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Marco Y. T. Leung, C. M. Shun, S. M. Lee, and H. W. Tong, 2016: A strong phase reversal of the Arctic Oscillation in midwinter 2015\/2016: Role of the stratospheric polar vortex and tropospheric blocking. <em>Journal of Geophysical Research: Atmospheres<\/em>, 121, 13, 443-413, 457. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/2016JD025288\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2016: Direct and indirect ENSO modulation of winter temperature over the Asian\u2013Pacific\u2013American region. <em>Scientific Reports<\/em>, 6, 36356. <a href=\"https:\/\/doi.org\/10.1038\/srep36356\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Edward Yan Yung Ng, and Yong Xu, 2016: Urban heat islands in Hong Kong: statistical modeling and trend detection. <em>Natural Hazards<\/em>, 83, 885-907. <a href=\"https:\/\/doi.org\/10.1007\/s11069-016-2353-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Yu-Ting Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2016: Eddy contributions at multiple timescales to the evolution of persistent anomalous East Asian trough. <em>Climate Dynamics<\/em>, 46, 2287-2303. <a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2702-2\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2016: Simple metrics for representing East Asian winter monsoon variability: Urals blocking and western Pacific teleconnection patterns. <em>Advances in Atmospheric Sciences<\/em>, 33, 695-705. <a href=\"https:\/\/doi.org\/10.1007\/s00376-015-5204-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Xiuzhen Li, Xin Wang, and Dongxiao Wang, 2016: Synoptic-scale characteristics and atmospheric controls of summer heat waves in China. <em>Climate Dynamics<\/em>, 46, 2923-2941.<a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2741-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Gang Huang*, <strong>\u5468\u6587<\/strong>, and Wen Chen, 2016: Historical change and future scenarios of sea level rise in Macau and adjacent waters. <em>Advances in Atmospheric Sciences<\/em>, 33, 462-475. <a href=\"https:\/\/doi.org\/10.1007\/s00376-015-5047-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, and Yongqin David Chen, 2016: Detecting the origins of moisture over southeast China: Seasonal variation and heavy rainfall. <em>Advances in Atmospheric Sciences<\/em>, 33, 319-329. <a href=\"https:\/\/doi.org\/10.1007\/s00376-015-4197-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Tao Feng, Xiu-Qun Yang*, <strong>\u5468\u6587<\/strong>, Ronghui Huang, Liang Wu, and Dejian Yang, 2016: Synoptic-Scale Waves in Sheared Background Flow over the Western North Pacific. <em>Journal of the Atmospheric Sciences<\/em>, 73, 4583-4603. <a href=\"https:\/\/doi.org\/10.1175\/JAS-D-16-0064.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Wen Chen*, <strong>\u5468\u6587<\/strong>, and Gang Huang, 2016: Understanding and detecting super-extreme droughts in Southwest China through an integrated approach and index. <em>Quarterly Journal of the Royal Meteorological Society<\/em>, 142, 529-535. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/qj.2593\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Li Xiuzhen, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2016: Modulation of the interannual variation of the India-Burma Trough on the winter moisture supply over Southwest China. <em>Climate Dynamics<\/em>, 46, 147-158. <a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2575-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2015<\/h3><p>Lin Wang, Wen Chen*, <strong>\u5468\u6587<\/strong>, and Gang Huang, 2015: Teleconnected influence of tropical Northwest Pacific sea surface temperature on interannual variability of autumn precipitation in Southwest China. <em>Climate Dynamics<\/em>, 45, 2527-2539. <a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2490-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Yu-Ting Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2015: Variation of circulation and East Asian climate associated with anomalous strength and displacement of the East Asian trough. <em>Climate Dynamics<\/em>, 45, 2713-2732. <a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2504-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jiangjiang Xia*, Zhongwei Yan, <strong>\u5468\u6587<\/strong>, Soi Kun Fong, Ka Cheng Leong, Iu Man Tang, S. W. Chang, W. K. Leong, and Shaofei Jin, 2015: Projection of the Zhujiang (Pearl) River Delta\u2019s potential submerged area due to sea level rise during the 21st century based on CMIP5 simulations. <em>Acta Oceanologica Sinica<\/em>, 34, 78-84. <a href=\"https:\/\/doi.org\/10.1007\/s13131-015-0700-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, and Yongqin David Chen, 2015: Assessment of Regional Drought Trend and Risk over China: A Drought Climate Division Perspective. <em>Journal of Climate<\/em>, 28, 7025-7037. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00403.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Yu-Ting Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2015: Vertical structure, physical properties, and energy exchange of the East Asian trough in boreal winter. <em>Climate Dynamics<\/em>, 45, 1635-1656. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2419-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2015: Multiscale control of summertime persistent heavy precipitation events over South China in association with synoptic, intraseasonal, and low-frequency background. <em>Climate Dynamics<\/em>, 45, 1043-1057. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2347-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jiangjiang Xia*, Zhongwei Yan, Gensuo Jia, Heqing Zeng, Philip Douglas Jones, <strong>\u5468\u6587<\/strong>, and Anzhi Zhang, 2015: Projections of the advance in the start of the growing season during the 21st century based on CMIP5 simulations. <em>Advances in Atmospheric Sciences<\/em>, 32, 831-838. <a href=\"https:\/\/doi.org\/10.1007\/s00376-014-4125-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Yun Li, Xin Wang, and Dongxiao Wang, 2015: Statistical modeling and CMIP5 simulations of hot spell changes in China. <em>Climate Dynamics<\/em>, 44, 2859-2872. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2287-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Kun-Hui Ye, Chi-Yung Tam*, <strong>\u5468\u6587<\/strong>, and Soo-Jin Sohn, 2015: Seasonal prediction of June rainfall over South China: Model assessment and statistical downscaling. <em>Advances in Atmospheric Sciences<\/em>, 32, 680-689. <a href=\"https:\/\/doi.org\/10.1007\/s00376-014-4047-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Yu-Ting Leung, Hoffman Ho-Nam Cheung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2015: Energetics and dynamics associated with two typical mobile trough pathways over East Asia in boreal winter. <em>Climate Dynamics<\/em>, 44, 1611-1626. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2355-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang*, Wen Chen, <strong>\u5468\u6587<\/strong>, and Gang Huang, 2015: Drought in Southwest China: A Review. <em>Atmos. 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Cheung, <strong>\u5468\u6587<\/strong>*, Sai-ming Lee, and Hang-wai Tong, 2015: Interannual and Interdecadal Variability of the Number of Cold Days in Hong Kong and Their Relationship with Large-Scale Circulation. <em>Monthly Weather Review<\/em>, 143, 1438-1454. <a href=\"https:\/\/doi.org\/10.1175\/MWR-D-14-00335.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong>*, Soi Kun Fong, Ka Cheng Leong, Iu Man Tang, Sau Wa Chang, and Weng Kun Leong, 2015: Extreme rainfall and summer heat waves in Macau based on statistical theory of extreme values. <em>Climate Reseach<\/em>, 66:91-101. <a href=\"https:\/\/doi.org\/10.3354\/cr01336\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, <strong>\u5468\u6587<\/strong>*, and Tsz Cheung Lee, 2015: Climatological Characteristics and Observed Trends of Tropical Cyclone\u2013Induced Rainfall and Their Influences on Long-Term Rainfall Variations in Hong Kong. <em>Monthly Weather Review<\/em>, 143, 2192-2206. <a href=\"https:\/\/doi.org\/10.1175\/MWR-D-14-00332.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2015: Interdecadal Changes in Summertime Tropical Cyclone Precipitation over Southeast China during 1960\u20132009. <em>Journal of Climate<\/em>, 28, 1494-1509. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00246.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Qian Cheng*, <strong>\u5468\u6587<\/strong>, Soi Kun Fong, and Ka Cheng Leong, 2015: Two Approaches for Statistical Prediction of Non-Gaussian Climate Extremes: A Case Study of Macao Hot Extremes during 1912\u20132012. <em>Journal of Climate<\/em>, 28, 623-636. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00159.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2014<\/h3><p>Xia Qu, Gang Huang*, and <strong>\u5468\u6587<\/strong>, 2014: Consistent responses of East Asian summer mean rainfall to global warming in CMIP5 simulations. <em>Theoretical and Applied Climatology<\/em>, 117, 123-131. <a href=\"https:\/\/doi.org\/10.1007\/s00704-013-0995-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, <strong>\u5468\u6587<\/strong>*, Chongyin Li, and Dongxiao Wang, 2014: Comparison of the impact of two types of El Ni\u00f1o on\u00a0tropical cyclone genesis over the South China Sea. <em>International Journal of Climatology<\/em>, 34, 2651-2660. <a href=\"https:\/\/doi.org\/10.1002\/joc.3865\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Dongxiao Wang*, Xin Wang, <strong>\u5468\u6587<\/strong>, and Chongyin Li, 2014: Comparisons of Two Types of El Ni\u00f1o Impacts on TC Genesis over the South China Sea. <em>Advances in Natural and Technological Hazards Research<\/em>, vol 40. <a href=\"https:\/\/doi.org\/10.1007\/978-3-642-40695-9_17\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, <strong>\u5468\u6587<\/strong>*, and Tim Li, 2014: Influences of the Pacific\u2013Japan Teleconnection Pattern on Synoptic-Scale Variability in the Western North Pacific. <em>Journal of Climate<\/em>, 27, 140-154. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-13-00183.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, <strong>\u5468\u6587<\/strong>*, Deliang Chen, Chongyin Li, and Jie Song, 2014: Water Vapor Transport and Moisture Budget over Eastern China: Remote Forcing from the Two Types of El Ni\u00f1o. <em>Journal of Climate<\/em>, 27, 8778-8792. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00049.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2014: Interdecadal Change in South China Sea Tropical Cyclone Frequency in Association with Zonal Sea Surface Temperature Gradient. <em>Journal of Climate<\/em>, 27, 5468-5480. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-13-00744.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Wen Chen*, and <strong>\u5468\u6587<\/strong>, 2014: Assessment of future drought in Southwest China based on CMIP5 multimodel projections. <em>Advances in Atmospheric Sciences<\/em>, 31, 1035-1050. <a href=\"https:\/\/doi.org\/10.1007\/s00376-014-3223-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuyun Liu, Lin Wang*, <strong>\u5468\u6587<\/strong>, and Wen Chen, 2014: Three Eurasian teleconnection patterns: spatial structures, temporal variability, and associated winter climate anomalies. <em>Climate Dynamics<\/em>, 42, 2817-2839. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2163-z\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong>*, and Deliang Chen, 2014: Summer High Temperature Extremes in Southeast China: Bonding with the El Ni\u00f1o\u2013Southern Oscillation and East Asian Summer Monsoon Coupled System. <em>Journal of Climate<\/em>, 27, 4122-4138. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/27\/11\/jcli-d-13-00545.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song*, Chongyin Li, and <strong>\u5468\u6587<\/strong>, 2014: High and low latitude types of the downstream influences of the North Atlantic Oscillation. <em>Climate Dynamics<\/em>, 42, 1097-1111. <a href=\"https:\/\/doi.org\/10.1007\/s00382-013-1844-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jian Ling*, Chongyin Li, <strong>\u5468\u6587<\/strong>, and Xiaolong Jia, 2014: To begin or not to begin? A case study on the MJO initiation problem. <em>Theoretical and Applied Climatology<\/em>, 115, 231-241. <a href=\"https:\/\/doi.org\/10.1007\/s00704-013-0889-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang*, Mark Wenig, <strong>\u5468\u6587<\/strong>, Thomas Diehl, Ka-Lok Chan, and Lingna Wang, 2014: The contribution of different aerosol sources to the Aerosol Optical Depth in Hong Kong. <em>Atmospheric Environment<\/em>, 83, 145-154. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1352231013008005\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2013<\/h3><p>Xiuzhen Li, <strong>\u5468\u6587<\/strong>*, Chongyin Li, and Jie Song, 2013: Comparison of the Annual Cycles of Moisture Supply over Southwest and Southeast China. <em>Journal of Climate<\/em>, 26, 10139-10158. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/26\/24\/jcli-d-13-00057.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xianjun Xiao*, Dongxiao Wang , <strong>\u5468\u6587<\/strong>, Zuqiang Zhang, Yinghao Qin, Na He, and Lili Zeng, 2013: Impacts of a wind stress and a buoyancy flux on the seasonal variation of mixing layer depth in the South China Sea. <em>Acta Oceanologica Sinica<\/em>, 32, 30-37. <a href=\"https:\/\/doi.org\/10.1007\/s13131-013-0349-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong>*, Xin Wang, Soi Kun Fong, and Ka Cheng Leong, 2013: Summer high temperature extremes in Southeast China associated with the East Asian jet stream and circumglobal teleconnection. <em>Journal of Geophysical Research: Atmospheres<\/em>, 118, 8306-8319. <a href=\"https:\/\/doi.org\/10.1002\/jgrd.50633\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Qun Zhou, Wen Chen*, and <strong>\u5468\u6587<\/strong>, 2013: Solar cycle modulation of the ENSO impact on the winter climate of East Asia. <em>Journal of Geophysical Research: Atmospheres<\/em>, 118, 5111-5119. <a href=\"https:\/\/doi.org\/10.1002\/jgrd.50453\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2013: Modulation of Western North Pacific Tropical Cyclone Activity by the ISO. Part II: Tracks and Landfalls. <em>Journal of Climate<\/em>26, 2919-2930. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-12-00211.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2013: Modulation of Western North Pacific Tropical Cyclone Activity by the ISO. Part I: Genesis and Intensity. <em>Journal of Climate<\/em>, 26, 2904-2918. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-12-00210.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, <strong>Wen Zhou*<\/strong>, Hing Yim Mok, Man Chi Wu, and Yaping Shao, 2013: Revisiting the climatology of atmospheric blocking in the Northern Hemisphere. <em>Advances in Atmospheric Sciences<\/em>, 30, 397-410. <a href=\"https:\/\/doi.org\/10.1007\/s00376-012-2006-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jong-Suk Kim, <strong>\u5468\u6587<\/strong>*, Hoffman H. N. Cheung, and <a href=\"https:\/\/link.springer.com\/article\/10.1007\/s00376-012-2074-z#auth-Chak_Hang-Chow-Aff1-Aff2\">Chak Hang Chow<\/a>, 2013: Variability and risk analysis of Hong Kong air quality based on Monsoon and El Ni\u00f1o conditions. <em>Advances in Atmospheric Sciences<\/em>, 30, 280-290. <a href=\"https:\/\/doi.org\/10.1007\/s00376-012-2074-z\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, <strong>\u5468\u6587<\/strong>*, Dongxiao Wang , and Chunzai Wang, 2013: The impacts of the summer Asian Jet Stream biases on surface air temperature in mid-eastern China in IPCC AR4 models. <em>International Journal of Climatology<\/em>, 33, 265-276. <a href=\"https:\/\/doi.org\/10.1002\/joc.3419\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, <strong>\u5468\u6587<\/strong>*, Yaping Shao, Wen Chen, Hing Yim Mok, and Man Chi Wu, 2013: Observational climatology and characteristics of wintertime atmospheric blocking over Ural\u2013Siberia. <em>Climate Dynamics<\/em>, 41, 63-79. <a href=\"https:\/\/doi.org\/10.1007\/s00382-012-1587-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang*, Chunzai Wang, <strong>\u5468\u6587<\/strong>, Lin Liu, and Dongxiao Wang , 2013: Remote influence of North Atlantic SST on the equatorial westerly wind anomalies in the western Pacific for initiating an El Ni\u00f1o event: an Atmospheric General Circulation Model Study. <em>Atmospheric Science Letters<\/em>, 14, 107-111. <a href=\"https:\/\/doi.org\/10.1002\/asl2.425\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jian Ling*, Chongyin Li, <strong>\u5468\u6587<\/strong>, Xiaolong Jia, and Chidong Zhang, 2013: Effect of boundary layer latent heating on MJO simulations. <em>Advances in Atmospheric Sciences<\/em>, 30, 101-115. <a href=\"https:\/\/doi.org\/10.1007\/s00376-012-2031-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2012<\/h3><p>Xiuzhen Li, and <strong>\u5468\u6587<\/strong>*, 2012: Quasi-4-Yr Coupling between El Ni\u00f1o\u2013Southern Oscillation and Water Vapor Transport over East Asia\u2013WNP. <em>Journal of Climate<\/em>, 25, 5879-5891. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-11-00433.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2012: Changes in Western Pacific Tropical Cyclones Associated with the El Ni\u00f1o\u2013Southern Oscillation Cycle. <em>Journal of Climate<\/em>25, 5864-5878. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-11-00430.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, <strong>\u5468\u6587<\/strong>*, Johnny C. L. Chan, and P. Huang, 2012: Asymmetric Modulation of Western North Pacific Cyclogenesis by the Madden\u2013Julian Oscillation under ENSO Conditions. <em>Journal of Climate<\/em>, 25, 5374-5385. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-11-00337.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>John Xun Yang, Alexis Kai Hon Lau*, Jimmy Chi Hung Fung, <strong>\u5468\u6587<\/strong>, Mark Wenig, 2012: An air pollution episode and its formation mechanism during the tropical cyclone Nuri\u2019s landfall in a coastal city of south China. <em>Atmospheric Environment<\/em>, 54, 746-753. <a href=\"https:\/\/doi.org\/10.1016\/j.atmosenv.2011.12.023\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, <strong>\u5468\u6587<\/strong>*, Hing Yim Mok, and Man Chi Wu, 2012: Relationship between Ural\u2013Siberian Blocking and the East Asian Winter Monsoon in Relation to the Arctic Oscillation and the El Ni\u00f1o\u2013Southern Oscillation. <em>Journal of Climate<\/em>, 25, 4242-4257. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-11-00225.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Huopo Chen*, Jianqi Sun, Xiaoli Chen, and <strong>\u5468\u6587<\/strong>, 2012: CGCM projections of heavy rainfall events in China. <em>International Journal of Climatology<\/em>, 32, 441-450. <a href=\"https:\/\/doi.org\/10.1002\/joc.2278\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, <strong>\u5468\u6587<\/strong>*, Chongyin Li, and Dongxiao Wang , 2012: Effects of the East Asian summer monsoon on tropical cyclone genesis over the South China Sea on an interdecadal time scale. <em>Advances in Atmospheric Sciences<\/em>, 29, 249-262. <a href=\"https:\/\/doi.org\/10.1007\/s00376-011-1080-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jong-Suk Kim, <strong>\u5468\u6587<\/strong>*, Xin Wang, and Shaleen Jain, 2012: El Ni\u00f1o Modoki and the Summer Precipitation Variability over South Korea: A Diagnostic Study. <em>Journal of the Meteorological Society of Japan. 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Beggs, and <strong>\u5468\u6587<\/strong>, 2012: On two different objective procedures for classifying synoptic weather types over east Australia. <em>International Journal of Climatology<\/em>, 32, 1475-1494. <a href=\"https:\/\/doi.org\/10.1002\/joc.2373\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuan Fang, Wen Chen*, and <strong>\u5468\u6587<\/strong>, 2012: Analysis of the role played by circulation in the persistent precipitation over South China in June 2010. <em>Advances in Atmospheric Sciences<\/em>, 29, 769-781. <a href=\"https:\/\/doi.org\/10.1007\/s00376-012-2018-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Youfang Yan*, Yiquan Qi, and <strong>\u5468\u6587<\/strong>, 2012: Variability of tropical cyclone occurrence date in the South China Sea and its relationship with SST warming. <em>Dynamics of Atmospheres and Oceans<\/em>, 55-56, 45-59. <a href=\"https:\/\/doi.org\/10.1016\/j.dynatmoce.2012.05.001\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Qizhong Wu, Zifa Wang, Huansheng Chen, <strong>\u5468\u6587<\/strong>*, and Mark Wenig, 2012: An evaluation of air quality modeling over the Pearl River Delta during November 2006. <em>Meteorology and Atmospheric Physics<\/em>, 116, 113-132. <a href=\"https:\/\/doi.org\/10.1007\/s00703-011-0179-z\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>*, Wen Chen, and Dongxiao Wang, 2012: The implications of El Ni\u00f1o-Southern Oscillation signal for South China monsoon climate. <em>Aquatic Ecosystem Health &amp; Management<\/em>, 15, 14-19. <a href=\"https:\/\/doi.org\/10.1080\/14634988.2012.652050\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, Dongxiao Wang , <strong>\u5468\u6587<\/strong>*, and Chongyin Li, 2012: Interdecadal modulation of the influence of La Ni\u00f1a events on mei-yu rainfall over the Yangtze River valley. <em>Advances in Atmospheric Sciences<\/em> ,29, 157-168. <a href=\"https:\/\/doi.org\/10.1007\/s00376-011-1021-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2011<\/h3><p>Weiwen Wang, Dongxiao Wang*, <strong>\u5468\u6587<\/strong>, Qinyan Liu, Yongqiang Yu, and Chao Li, 2011: Impact of the South China Sea throughflow on the pacific low-latitude western boundary current: A numerical study for seasonal and interannual time scales. <em>Advances in Atmospheric Sciences<\/em>, 28, 1367-1376. <a href=\"https:\/\/doi.org\/10.1007\/s00376-011-0142-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song*, <strong>\u5468\u6587<\/strong>, Xin Wang, and Chongyin Li, 2011: Zonal Asymmetry of the Annular Mode and Its Downstream Subtropical Jet: An Idealized Model Study. <em>Journal of the Atmospheric Sciences<\/em>, 68, 1946-1973. <a href=\"https:\/\/doi.org\/10.1175\/2011JAS3656.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ren-Jun Zhou*, Peng-Bing Liu, <strong>\u5468\u6587<\/strong>, Hong-Ke Cai, and Yue-Juan Chen, 2011: The analysis of quasi-biennial oscillation characteristics of stratospheric aerosol. <em>Acta Geophysica Sinica<\/em>, 54, 1174-1181. <a href=\"https:\/\/doi.org\/10.3969\/j.issn.0001-5733.2011.05.005\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhongwei Yan, Jiangjiang Xia, Cheng Qian, and <strong>\u5468\u6587<\/strong>*, 2011: Changes in seasonal cycle and extremes in China during the period 1960\u20132008. <em>Advances in Atmospheric Sciences<\/em>, 28, 269-283. <a href=\"https:\/\/doi.org\/10.1007\/s00376-010-0006-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>JIangjiang Xia, Zhongwei Yan*, and <strong>\u5468\u6587<\/strong>, 2011: Changes in Seasonality in China under Enhanced Atmospheric CO2 Concentration. <em>Atmospheric and Oceanic Science Letters<\/em>, 4, 12-17. <a href=\"https:\/\/doi.org\/10.1080\/16742834.2011.11446900\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Juan Feng, Wen Chen*, C.-Y. 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Chan, 2010: Influence of South China Sea SST and the ENSO on winter rainfall over South China. <em>Advances in Atmospheric Sciences<\/em>, 27, 832-844. <a href=\"https:\/\/doi.org\/10.1007\/s00376-009-9102-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Qinyan Liu*, Dongxiao Wang, <strong>\u5468\u6587<\/strong>, Qiang Xie, and Yan Zhang, 2010: Covariation of the Indonesian throughflow and South China Sea throughflow associated with the 1976\/77 regime shift. <em>Advances in Atmospheric Sciences<\/em>, 27, 87-94. <a href=\"https:\/\/doi.org\/10.1007\/s00376-009-8061-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Wen Chen*, <strong>\u5468\u6587<\/strong>, Johnny C. L. Chan, David Barriopedro, and Ronghui Huang, 2010: Effect of the climate shift around mid 1970s on the relationship between wintertime Ural blocking circulation and East Asian climate. <em>International Journal of Climatology<\/em>, 30, 153-158. <a href=\"https:\/\/doi.org\/10.1002\/joc.1876\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Dehai Luo*, <strong>\u5468\u6587<\/strong>, and Ke Wei, 2010: Dynamics of eddy-driven North Atlantic Oscillations in a localized shifting jet: zonal structure and downstream blocking. <em>Climate Dynamics<\/em>, 34, 73-100. <a href=\"https:\/\/doi.org\/10.1007\/s00382-009-0559-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2009<\/h3><p><strong>\u5468\u6587<\/strong>*, Johnny C. L. Chan, Wen Chen, Jian Ling, Joaquim G. Pinto, and Yaping Shao, 2009: Synoptic-Scale Controls of Persistent Low Temperature and Icy Weather over Southern China in January 2008. <em>Monthly Weather Review<\/em>, 137, 3978-3991. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/mwre\/137\/11\/2009mwr2952.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song, <strong>\u5468\u6587<\/strong>*, Chongyin Li, and Lixin Qi, 2009: Signature of the Antarctic oscillation in the northern hemisphere. <em>Meteorology and Atmospheric Physics<\/em>, 105, 55-67. <a href=\"https:\/\/doi.org\/10.1007\/s00703-009-0036-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Wei Gu*, Chongyin Li, Weijing Li, <strong>\u5468\u6587<\/strong>, and Johnny C. L. Chan, 2009: Interdecadal unstationary relationship between NAO and east China\u2019s summer precipitation patterns. <em>Geophysical Research Letters<\/em>, 36. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2009GL038843\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Wei Gu*, Chongyin Li, Xin Wang, <strong>\u5468\u6587<\/strong>, and Weijing Li, 2009: Linkage between mei-yu precipitation and North Atlantic SST on the decadal timescale. <em>Advances in Atmospheric Sciences<\/em>, 26, 101-108. <a href=\"https:\/\/doi.org\/10.1007\/s00376-009-0101-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang*, Dongxiao Wang, and <strong>\u5468\u6587<\/strong>, 2009: Decadal variability of twentieth-century El Ni\u00f1o and La Ni\u00f1a occurrence from observations and IPCC AR4 coupled models. <em>Geophysical Research Letters<\/em>, 36. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2009GL037929\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song*, Chongyin Li, <strong>\u5468\u6587<\/strong>, and Jing Pan, 2009: The linkage between the Pacific-North American teleconnection pattern and the North Atlantic Oscillation. <em>Advances in Atmospheric Sciences<\/em>, 26, 229-239. <a href=\"https:\/\/doi.org\/10.1007\/s00376-009-0229-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Wen Chen*, <strong>\u5468\u6587<\/strong>, and Ronghui Huang, 2009: Interannual Variations of East Asian Trough Axis at 500 hPa and its Association with the East Asian Winter Monsoon Pathway. <em>Journal of Climate<\/em>, 22, 600-614. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/22\/3\/2008jcli2295.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>H.W. Tong, Johnny C. L. Chan*, and <strong>\u5468\u6587<\/strong>, 2009: The role of MJO and mid-latitude fronts in the South China Sea summer monsoon onset. <em>Climate Dynamics<\/em>, 33, 827-841. <a href=\"https:\/\/doi.org\/10.1007\/s00382-008-0490-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hong-Ming Yan*, Chong-Yin Li, and <strong>\u5468\u6587<\/strong>, 2009: Influence of subtropical dipole pattern in Southern Indian Ocean on ENSO event. <em>Acta Geophysica Sinica<\/em>, 52, 2436-2449. <a href=\"https:\/\/doi.org\/10.3969\/j.issn.0001-5733.2009.10.003\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Chongyin Li, Xiaolong Jia, Jian Ling, <strong>\u5468\u6587<\/strong>, and Chidong Zhang*, 2009: Sensitivity of MJO simulations to diabatic heating profiles. <em>Climate Dynamics<\/em>, 32, 167-187. <a href=\"https:\/\/doi.org\/10.1007\/s00382-008-0455-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2008<\/h3><p>Yuan Yuan*, Johnny C. L. Chan, <strong>\u5468\u6587<\/strong>, and Chongyin Li, 2008: Decadal and interannual variability of the Indian Ocean Dipole. <em>Advances in Atmospheric Sciences<\/em>, 25, 856-866. <a href=\"https:\/\/doi.org\/10.1007\/s00376-008-0856-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuan Yuan*, Hui Yang, <strong>\u5468\u6587<\/strong>, and Chongyin Li, 2008: Influences of the Indian Ocean dipole on the Asian summer monsoon in the following year. <em>International Journal of Climatology<\/em>, 28, 1849-1859. <a href=\"https:\/\/doi.org\/10.1002\/joc.1678\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuan Yuan*, <strong>\u5468\u6587<\/strong>, Hui Yang, and Chongyin Li, 2008: Warming in the northwestern Indian Ocean associated with the El Ni\u00f1o event. <em>Advances in Atmospheric Sciences<\/em>, 25, 246-252. <a href=\"https:\/\/doi.org\/10.1007\/s00376-008-0246-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuan Yuan, <strong>\u5468\u6587<\/strong>, Johnny C. L. Chan*, and Chongyin Li, 2008: Impacts of the basin-wide Indian Ocean SSTA on the South China Sea summer monsoon onset. <em>International Journal of Climatology<\/em>, 28, 1579-1587. <a href=\"https:\/\/doi.org\/10.1002\/joc.1671\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xuhua Cheng, Yiquan Qi*, and <strong>\u5468\u6587<\/strong>, 2008: Trends of sea level variations in the Indo-Pacific warm pool. <em>Global and Planetary Change<\/em>, 63, 57-66. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0921818108000647\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Martin L. M. Wong, Johnny C. L. Chan*, and <strong>\u5468\u6587<\/strong>, 2008: A Simple Empirical Model for Estimating the Intensity Change of Tropical Cyclones after Landfall along the South China Coast. <em>Journal of Applied Meteorology and Climatology<\/em>, 47, 326-338. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/apme\/47\/1\/2007jamc1633.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2007<\/h3><p><strong>\u5468\u6587<\/strong>*, Xin Wang, Tianjun Zhou, Chongyin Li, and Johnny C. L. Chan, 2007: Interdecadal variability of the relationship between the East Asian winter monsoon and ENSO. <em>Meteorology and Atmospheric Physics<\/em>, 98, 283-293. <a href=\"https:\/\/doi.org\/10.1007\/s00703-007-0263-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, Chongyin Li, and <strong>\u5468\u6587<\/strong>*, 2007: Interdecadal mode and its propagating characteristics of SSTA in the South Pacific. <em>Meteorology and Atmospheric Physics<\/em>, 98, 115-124. <a href=\"https:\/\/doi.org\/10.1007\/s00703-006-0235-2\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Dehai Luo*, Tingting Gong, Yina Diao, and <strong>\u5468\u6587<\/strong>, 2007: Storm tracks and annular modes. <em>Geophysical Research Letters<\/em>, 34. <a href=\"https:\/\/doi.org\/10.1029\/2007GL030436\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>, and Johnny C. L. Chan*, 2007: ENSO and the South China Sea summer monsoon onset. <em>International Journal of Climatology<\/em>, 27, 157-167. <a href=\"https:\/\/doi.org\/10.1002\/joc.1380\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>, Chongyin Li, and Xin Wang*, 2007: Possible connection between Pacific Oceanic interdecadal pathway and east Asian winter monsoon. <em>Geophysical Research Letters<\/em>, 34. <a href=\"https:\/\/doi.org\/10.1029\/2006GL027809\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2006<\/h3><p>Chongyin Li*, <strong>\u5468\u6587<\/strong>, Xiaolong Jia, and Xin Wang, 2006: Decadal\/interdecadal variations of the ocean temperature and its impacts on climate. <em>Advances in Atmospheric Sciences<\/em>, 23, 964-981. <a href=\"https:\/\/doi.org\/10.1007\/s00376-006-0964-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song*, <strong>\u5468\u6587<\/strong>, Jing Pan, and Chongyin Li, 2006: Global influence of the Northern Hemisphere second mode of the zonal average of the zonal wind. <em>Geophysical Research Letters<\/em>, 33. <a href=\"https:\/\/doi.org\/10.1029\/2006GL026380\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>*, Chongyin Li, and Johnny C. L. Chan, 2006: The interdecadal variations of the summer monsoon rainfall over South China. <em>Meteorology and Atmospheric Physics<\/em>, 93, 165-175. <a href=\"https:\/\/doi.org\/10.1007\/s00703-006-0184-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang*, Chongyin Li, and <strong>\u5468\u6587<\/strong>, 2006: Interdecadal variation of the relationship between Indian rainfall and SSTA modes in the Indian Ocean. <em>International Journal of Climatology<\/em>, 26, 595-606. <a href=\"https:\/\/doi.org\/10.1002\/joc.1283\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2005<\/h3><p><strong>\u5468\u6587<\/strong>, and Johnny C. L. Chan*, 2005: Intraseasonal oscillations and the South China Sea summer monsoon onset. <em>International Journal of Climatology<\/em>, 25, 1585-1609. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/joc.1209\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Johnny C. L. Chan*, and <strong>\u5468\u6587<\/strong>, 2005: PDO, ENSO and the early summer monsoon rainfall over south China. <em>Geophysical Research Letters<\/em>, 32. <a href=\"https:\/\/doi.org\/10.1029\/2004GL022015\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>*, Johnny Chung-Leung Chan, and Chongyin Li, 2005: South China Sea summer monsoon onset in relation to the off-equatorial ITCZ. <em>Advances in Atmospheric Sciences<\/em>, 22, 665-676. <a href=\"https:\/\/doi.org\/10.1007\/BF02918710\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><\/div>\n\t\t\t\t\t\t\t\t\t<div class=\"elementor-tab-title elementor-tab-mobile-title\" aria-selected=\"false\" data-tab=\"2\" role=\"tab\" tabindex=\"-1\" aria-controls=\"elementor-tab-content-1122\" aria-expanded=\"false\">2025-2021<\/div>\n\t\t\t\t\t<div id=\"elementor-tab-content-1122\" class=\"elementor-tab-content elementor-clearfix\" data-tab=\"2\" role=\"tabpanel\" aria-labelledby=\"elementor-tab-title-1122\" tabindex=\"0\" hidden=\"hidden\"><h3>2025 \u00a0<\/h3><div><div><div><p>Zheng-Hang Fu, Dazhi Xi, Shang-Ping Xie, <strong>Wen Zhou*<\/strong>, Ning Lin, Jiuwei Zhao, Xin Wang, and Johnny C. L. Chan, 2025: Shifting hotspot of tropical cyclone clusters in a warming climate, Nature Climate Change, 15, accepted.<\/p><p>Widana A. E. Lakshani, <strong>Wen Zhou*<\/strong>, Johnny C. L. Chan, Xuan Wang, Jayarathana W. N. D. Sandaruwan, and Zekai Ni, 2025: Linkages between the Indian Ocean Basin Mode and tropical cyclone activity in the North Indian and Western North Pacific Oceans. Climate Dynamics, 63, 171. <a href=\"https:\/\/doi.org\/10.1007\/s00382-025-07637-4\">[Link to Paper]<\/a><\/p><p>Bo Tong, <strong>Wen Zhou*<\/strong>, and Xin Wang*, 2025: Rising warm positive Indian Ocean dipole under global warming: Early western Indian Ocean warming as a key predictor. One Earth, 8. <a href=\"https:\/\/doi.org\/10.1016\/j.oneear.2025.101277\">[Link to Paper]<\/a><\/p><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Ye Tian, <strong>Wen Zhou*<\/strong>, Paxson K. Y. Cheung, and Zhenchen Liu, 2025: Vision Transformer for Extracting Tropical Cyclone Intensity from Satellite Images. <i>Advances in Atmospheric Sciences<\/i>, 42, 79-93. <a href=\"https:\/\/doi.org\/10.1007\/s00376-024-3191-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><\/div><p><span lang=\"EN-US\">Zhuoying Li, and <strong>Wen Zhou*<\/strong>, 2025: Westward shift of western North Pacific tropical cyclones in CMIP6-HighResMIP models. <i>Atmospheric and Oceanic Science Letters<\/i>, 100594. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283425000066\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p><span lang=\"EN-US\">Ruhua Zhang, <strong>Wen Zhou*<\/strong>, and Wenshou Tian, 2025: Holton-Tan effect enhances the influence of the QBO on the surface air temperature around the North Pacific. <i>Climate Dynamics<\/i>, 63, 128. <a href=\"https:\/\/doi.org\/10.1007\/s00382-024-07480-z\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Ruhua Zhang, <strong>Wen Zhou*<\/strong>, Yue Zhang, and Xiran Xu, 2025: Modulation of the Quasi-Biennial Oscillation on the East Asian Surface Air Temperature in Boreal Winter. <i>Journal of Climate<\/i>, 38, 87-99. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/38\/1\/JCLI-D-24-0207.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p><span lang=\"EN-US\">Lili Lei, Jianfang Fei, and <strong>\u5468\u6587<\/strong>, 2025: Theory and prediction of tropical cyclones and induced precipitation. <i>Atmospheric and Oceanic Science Letters<\/i>, 18, 100608. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283425000200\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p>Weiwei Zhang, Dongxiao Wang, Marco Y. T. Leung*, Lin Wang, Jinchi Xie, and <strong>\u5468\u6587<\/strong>, 2025: Upper-ocean cooling rate of the South China Sea in response to extreme cold surges and weak cold-air invasions. Atmospheric and Oceanic Science Letters, 18, 100517. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283424000667\">[Link to Paper]<\/a><\/p><p>Lixia Pan, Jiepeng Chen*, Xin Wang*, Haigang Zhan, <strong>\u5468\u6587<\/strong>, and Johnny C. L. Chan, 2025: More autumn tropical cyclone genesis in the South China Sea during El Ni\u00f1o to La Ni\u00f1a transition. npj Climate and Atmospheric Science, 8, 55. <a href=\"https:\/\/doi.org\/10.1038\/s41612-025-00947-8\">[Link to Paper]<\/a><\/p><\/div><h3>\u00a0<\/h3><h3>2024 \u00a0<\/h3><p>Zheng-Hang Fu, <strong>Wen Zhou*<\/strong>, Shang-Ping Xie*, Ruhua Zhang, and Xudong Wang, 2024: Dynamic pathway linking Pakistan flooding to East Asian heatwaves. <em>Science Advances<\/em>, 10, eadk9250. <a href=\"https:\/\/doi.org\/10.1126\/sciadv.adk9250\">[\u8bba\u6587\u4e3b\u9875]<\/a> <a href=\"https:\/\/www.science.org\/toc\/sciadv\/10\/17\">[Magazine cover]<\/a><\/p><p>Ruhua Zhang, <strong>Wen Zhou*<\/strong>, Wenshou Tian, Yue Zhang, Junxia Zhang, and Jiali Luo, 2024: A stratospheric precursor of East Asian summer droughts and floods. <em>Nature Communications<\/em>, 15, 247. <a href=\"https:\/\/doi.org\/10.1038\/s41467-023-44445-y\" target=\"_blank\" rel=\"noopener\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><div><div><p><span lang=\"EN-US\">Shifei Tu, Zhenzhen Hu, Mei Liang, <strong>Wen Zhou*<\/strong>, Johnny C. L. Chan, and Jianjun Xu*, 2024: Decreasing trend in destructive potential of tropical cyclones in the South Indian Ocean since the mid-1990s. <i>Communications Earth &amp; Environment<\/i>, 5, 543.<a href=\"https:\/\/doi.org\/10.1038\/s43247-024-01683-2\"> [\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p>Zhuoying Li, and <strong>Wen Zhou*<\/strong>, 2024: Poleward migration of tropical cyclones over the western North Pacific in the CMIP6-HighResMIP models constrained by observations. <i>npj Climate and Atmospheric Science<\/i>, 7, 161. <a href=\"https:\/\/doi.org\/10.1038\/s41612-024-00704-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Hongjie Liang, and <strong>Wen Zhou*<\/strong>, 2024: Dynamic and thermodynamic processes related to sea-ice surface melt advance in the Laptev Sea and East Siberian Sea. <i>The Cryosphere<\/i>, 18, 3559-3569. <a href=\"https:\/\/tc.copernicus.org\/articles\/18\/3559\/2024\/\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Zhenchen Liu, <strong>Wen Zhou*<\/strong>, and Xin Wang, 2024: Extreme Meteorological Drought Events over China (1951\u20132022): Migration Patterns, Diversity of Temperature Extremes, and Decadal Variations. <i>Advances in Atmospheric Sciences<\/i>. <a href=\"https:\/\/doi.org\/10.1007\/s00376-024-4004-2\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><\/div><\/div><p>Xiuzhen Li*, Zhiping Wen, and <strong>\u5468\u6587<\/strong>, 2024: Different configurations of the Eurasian pattern and South Asian jet wave train and their impacts on the winter climate over East Asia. <em>Climate Dynamics<\/em>. <a href=\"https:\/\/doi.org\/10.1007\/s00382-024-07176-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><div><div><span lang=\"EN-US\">Xiaoli Zhou, <strong>Wen Zhou*<\/strong>, Dongxiao Wang, Qiang Xie, Lei Yang*, and Qihua Peng, 2024: Westerlies Affecting the Seasonal Variation of Water Vapor Transport over the Tibetan Plateau Induced by Tropical Cyclones in the Bay of Bengal. <i>Advances in Atmospheric Sciences<\/i>, 41, 881-893. <a href=\"https:\/\/doi.org\/10.1007\/s00376-023-3093-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/div><div>\u00a0<\/div><\/div><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Chao He*, Xiaolong Chen, Matthew Collins, Fengfei Song, Yamin Hu, Xingwen Jiang, Yanju Liu, Yihui Ding, and <strong>\u5468\u6587<\/strong>, 2024: Rising geopotential height under global warming. <i>Climate Dynamics<\/i>. <a href=\"https:\/\/doi.org\/10.1007\/s00382-024-07175-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Xiaocheng Yu, Yue Zhang*, and <strong>\u5468\u6587<\/strong>, 2024: Distinct preceding oceanic drivers for interannual variation of summer tropical cyclone\u2013induced rainfall in South and East China. <i>Climate Dynamics<\/i>. <a href=\"https:\/\/doi.org\/10.1007\/s00382-024-07206-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><p>Jiasi Chen, Yuanhong Guan*, <strong>Wen Zhou,<\/strong> Xianghua Wu, Qifeng Lu, and Xingyu Li, 2024: Influence of the Southern Indian Ocean Dipole on the following spring climate in China: A synthetic observational and numerical study. <em>Atmospheric Research<\/em>, 299, 107183. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S016980952300580X\" target=\"_blank\" rel=\"noopener\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiaorui Zhang, Xiao Lu*, Fan Wang, <strong>Wen Zhou,<\/strong> Peng Wang, and Meng Gao*, 2024: Enhanced Late Spring Ozone in Southern China by Early Onset of the South China Sea Summer Monsoon. <em>Journal of Geophysical Research: Atmospheres<\/em>, 129, e2023JD039029. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2023JD039029\" target=\"_blank\" rel=\"noopener\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Oluwafemi E. Adeyeri, <strong>Wen Zhou*<\/strong>, Christopher E. Ndehedehe, and Xuan Wang, 2024: Global vegetation, moisture, thermal and climate interactions intensify compound extreme events. <em>Science of the Total Environment<\/em>, 912, 169261. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0048969723078919\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><div><p><span lang=\"EN-US\">Yue Zhang, <strong>Wen Zhou*<\/strong>, and Ruhua Zhang, 2024: Decadal Changes in Dry and Wet Heatwaves in Eastern China: Spatial Patterns and Risk Assessment. <i>Advances in Atmospheric Sciences<\/i>, 41, 2011-2026. <a href=\"https:\/\/doi.org\/10.1007\/s00376-024-3261-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p>Yue Zhang, <strong>Wen Zhou*<\/strong>, Xiaocheng Yu, Ye Tian, and Ruhua Zhang, 2024: Long-term coupled variability of temperature and precipitation in eastern China and the underlying mechanisms. <em>Climate Dynamics<\/em>, 62, 1447-1465. <a href=\"https:\/\/doi.org\/10.1007\/s00382-023-06963-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><span lang=\"EN-US\">Xuan Tong, and <strong>Wen Zhou*<\/strong>, 2024: Assessing predictive attribution in NMME forecasts of summer precipitation in eastern china using deep learning. <i>npj Climate and Atmospheric Science<\/i>, 7, 304.<a href=\"https:\/\/doi.org\/10.1038\/s41612-024-00835-7\"> [\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><p>Xuan Tong, <strong>Wen Zhou*<\/strong>, and Jiangjiang Xia, 2024: Improving Boreal Summer Precipitation Predictions From the Global NMME Through Res34-Unet. <em>Geophysical Research Letters<\/em>, 51, e2023GL106391. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2023GL106391\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Oluwafemi E. Adeyeri*, <strong>Wen Zhou*,<\/strong> Christopher E. Ndehedehe, Xuan Wang, Kazeem A. Ishola, and Patrick Laux, 2024: Minimizing uncertainties in climate projections and water budget reveals the vulnerability of freshwater to climate change. <em>One Earth<\/em>, 7, 72-87. <a href=\"https:\/\/doi.org\/10.1016\/j.oneear.2023.12.013\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang, and <strong>Wen Zhou*<\/strong>, 2024: Influence of Internal Climate System Forcing on the Relationship Between North Atlantic Tropical Cyclones and Saharan Dust. <em>Journal of Geophysical Research: Atmospheres<\/em>, 129, e2023JD039766. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2023JD039766\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, and <strong>Wen Zhou*<\/strong>, 2024: Interdecadal variation of the monsoon trough and its relationship with tropical cyclone genesis over the South China Sea and Philippine Sea around the mid-2000s. <em>Climate Dynamics<\/em>. <a href=\"https:\/\/doi.org\/10.1007\/s00382-023-07096-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>Wen Zhou*,<\/strong> Jinxiao Li, Zixiang Yan, Zili Shen, Bo Wu, Bin Wang, Ronghua Zhang, and Zhijin Li*, 2024: Progress and future prospects of decadal prediction and data assimilation: A review. <em>Atmospheric and Oceanic Science Letters<\/em>, 17, 100441. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S167428342300140X\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>M. Pear Hossain, <strong>\u5468\u6587<\/strong>, Marco Y. T. Leung, and Hsiang-Yu Yuan*, 2024: Association of air pollution and weather conditions during infection course with COVID-19 case fatality rate in the United Kingdom. <em>Scientific reports<\/em>, 14, 683. <a href=\"https:\/\/doi.org\/10.1038\/s41598-023-50474-w\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuqing Wang, <strong>Wen Zhou*<\/strong>, and Chunzai Wang*, 2024: Physical mechanism of the rapid increase in intense and long-lived extreme heatwaves in the Northern Hemisphere since 1980.<em> Science China Earth Sciences<\/em>. <a href=\"https:\/\/doi.org\/10.1007\/s11430-023-1332-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Shuai-Lei Yao*, Renguang Wu*, Jing-Jia Luo, and <strong>\u5468\u6587<\/strong>, 2024: Competing impacts of tropical Pacific and Atlantic on Southern Ocean inter-decadal variability. <em>npj Climate and Atmospheric Science<\/em>, 7, 104. <a href=\"https:\/\/doi.org\/10.1038\/s41612-024-00662-w\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwei Zhang, Dongxiao Wang, Marco Y. T. Leung*, Lin Wang, Jinchi Xie, and <strong>\u5468\u6587<\/strong>, 2024: Upper-ocean cooling rate of the South China Sea in response to extreme cold surges and weak cold-air invasions. <em>Atmospheric and Oceanic Science Letters<\/em>, 100517. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283424000667\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><div><p class=\"EndNoteBibliography\"><span lang=\"EN-US\">Zixiang Yan, <strong>Wen Zhou*<\/strong>, Jinxiao Li, Xuedan Zhu, Yuxin Zang, and Liuyi Zhang, 2024: Skillful Seasonal Prediction of Global Onshore Wind Resources in SIDRI-ESS V1.0. <i>Sustainability<\/i>, 16, 7721. <a href=\"https:\/\/www.mdpi.com\/2071-1050\/16\/17\/7721\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><p><span lang=\"EN-US\">Zixiang Yan, Jinxiao Li*, <strong>\u5468\u6587<\/strong>, Zouxing Lin, Yuxin Zang, and Siyuan Li, 2024: Evaluation of Seasonal Prediction of Extreme Wind Resource Potential over China Based on a Dynamic Prediction System SIDRI-ESS V1.0. <i>Atmosphere<\/i>, 15, 1024. <a href=\"https:\/\/www.mdpi.com\/2073-4433\/15\/9\/1024\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/span><\/p><\/div><h3>2023<\/h3><p>Zhenchen Liu, and <strong>Wen Zhou*<\/strong>, 2023: Glo3DHydroClimEventSet(v1.0): A global-scale event set of hydroclimatic extremes detected with the 3D DBSCAN-based workflow (1951\u20132022). <em>International Journal of Climatology<\/em>, 43, 7722-7744. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/joc.8289\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zili Shen, <strong>Wen Zhou*<\/strong>, Jinxiao Li, and Johnny C. L. Chan, 2023: A frequent ice-free Arctic is likely to occur before the mid-21st century. <em>npj Climate and Atmospheric Science<\/em>, 6, 103. <a href=\"https:\/\/doi.org\/10.1038\/s41612-023-00431-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ho-Nam Cheung*, Nour-Eddine Omrani*, Fumiaki Ogawa, Noel Keenlyside, Hisashi Nakamura, and <strong>\u5468\u6587<\/strong>, 2023: Pacific oceanic front amplifies the impact of Atlantic oceanic front on North Atlantic blocking. <em>npj Climate and Atmospheric Science<\/em>, 6, 61. <a href=\"https:\/\/doi.org\/10.1038\/s41612-023-00370-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuanhong Guan*, Yuxin Li, <strong>\u5468\u6587<\/strong>, Lanjun Zou*, and Xiaohong Wang, 2023: Statistical characteristics and mechanism of the South Atlantic Ocean Dipole. <em>International Journal of Climatology<\/em>, 43, 6733-6744. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/joc.8231\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ye Tian, <strong>Wen Zhou*<\/strong>, Lin Zhang, Yue Zhang, and Ruhua Zhang, 2023: Changes in ENSO Modulation of the Distribution of Rapidly Intensifying Tropical Cyclones over the Western North Pacific in Boreal Autumn. <em>Journal of Climate<\/em>, 36, 7739-7753. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/36\/22\/JCLI-D-23-0084.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ruhua Zhang, and <strong>\u5468\u6587<\/strong>*, 2023: Decadal Change in the Linkage between QBO and the Leading Mode of Southeast China Winter Precipitation. <em>Journal of Climate<\/em>, 36, 7379-7392. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/36\/21\/JCLI-D-23-0028.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ran Dong, Yuanhong Guan*, <strong>Wen Zhou,<\/strong> and Chenguang Guo, 2023: Impact of Southern Indian ocean dipole via the ITCZ on winter and spring precipitation in China. <em>Atmospheric and Oceanic Science Letters<\/em>, 16, 100358. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283423000363\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hongjie Liang, and <strong>Wen Zhou*<\/strong>, 2023: Arctic Sea Ice Melt Onset in the Laptev Sea and East Siberian Sea in Association with the Arctic Oscillation and Barents Oscillation. <em>Journal of Climate<\/em>, 36, 6363-6373. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/36\/18\/JCLI-D-22-0791.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xuan Tong, Zhongwei Yan*, <strong>Wen Zhou*<\/strong>, Jiangjiang Xia, and Xiaowei Quan, 2023: Multidecadal Oceanic Modulation of Summer Precipitation in North China in 1200-Year Global Climate Simulations. <em>Journal of Climate<\/em>, 36, 6125-6138. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/36\/17\/JCLI-D-22-0693.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jinling Piao, Wen Chen*, Jin-Soo Kim, <strong>\u5468\u6587<\/strong>, Shangfeng Chen, Peng Hu, and Xiaoqing Lan, 2023: Future changes in rainy season characteristics over East China under continuous warming. <em>Climatic Change<\/em>, 176, 120. <a href=\"https:\/\/doi.org\/10.1007\/s10584-023-03598-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Bo Tong, and <strong>Wen Zhou*<\/strong>, 2023: Role of the Australian High in Seasonal Phase Locking of the Indian Ocean Dipole. <em>Geophysical Research Letters<\/em>, 50, e2022GL102174. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2022GL102174\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenchen Liu, <strong>Wen Zhou*<\/strong>, and Yuan Yuan, 2023: 3D DBSCAN detection and parameter sensitivity of the 2022 Yangtze river summertime heatwave and drought. <em>Atmospheric and Oceanic Science Letters<\/em>, 16, 100324. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283422002124\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Oluwafemi E. Adeyeri*, <strong>Wen Zhou*<\/strong>, Patrick Laux, Xuan Wang, Diarra Dieng, Lakshani A. E. Widana, and Muhammad Usman, 2023: Land use and land cover dynamics: Implications for thermal stress and energy demands. <em>Renewable and Sustainable Energy Reviews<\/em>, 179, 113274. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1364032123001302\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuntao Jian, Marco Y. T. Leung, Ruhua Zhang, <strong>\u5468\u6587<\/strong>, Maoqiu Jian, Song Yang, Yerong Feng, and Banglin Zhang*, 2023: Bias and Uncertainty of the Relationship between AO and Winter Synoptic Temperature Variability over the Northern Hemisphere under Present and Future Climate. <em>Journal of Climate<\/em>, 36, 3245-3259. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/36\/10\/JCLI-D-22-0230.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jayarathna W. N. D. Sandaruwan, <strong>Wen Zhou*<\/strong>, Paxson K. Y. Cheung, Yan Du, and Xuan Wang, 2023: Characteristics and Formation of Two Leading Marine Heatwave Modes in the North Indian Ocean during Summer and Their Implications for Local Precipitation. <em>Journal of Climate<\/em>, 36, 3385-3402. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/36\/10\/JCLI-D-22-0574.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Bo Tong, Xin Wang*, Dongxiao Wang, and <strong>\u5468\u6587<\/strong>, 2023: A Novel Mechanism for Extreme El Ni\u00f1o Events: Interactions between Tropical Cyclones in the Western North Pacific and Sea Surface Warming in the Eastern Tropical Pacific. <em>Journal of Climate<\/em>, 36, 2585-2601. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/36\/8\/JCLI-D-21-1014.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Oluwafemi E. Adeyeri*, <strong>Wen Zhou*<\/strong>, Patrick Laux, Christopher E. Ndehedehe, Xuan Wang, Muhammad Usman, and Akintomide A. 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Leung, Dongxiao Wang, <strong>Wen Zhou*<\/strong>, and Yuntao Jian, 2023: Extended Impact of Cold Air Invasions in East Asia in Response to a Warm South China Sea and Philippine Sea. <em>Advances in Atmospheric Sciences<\/em>, 40, 531-540. <a href=\"https:\/\/doi.org\/10.1007\/s00376-022-2096-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Widana Arachchige Erandani Lakshani, and <strong>Wen Zhou*<\/strong>, 2023: Observed decadal shifts and trends in global tropical cyclone activities from 1980 to 2021. <em>Atmospheric and Oceanic Science Letters<\/em>, 16, 100321. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283422002094\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuanhong Guan, <strong>Wen Zhou*<\/strong>, Xiaolong Jia, Yue Zhang, and Ran Dong, 2023: The synergistic impact of SPOD and ENSO on ITCZ: observation study. <em>Climate Dynamics<\/em>, 60, 1297-1311. <a href=\"https:\/\/doi.org\/10.1007\/s00382-022-06335-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Han Zhou*, <strong>Wen Zhou*<\/strong>, Yuanbo Liu*, Jiejun Huang*, Yanbin Yuan*, and Yongwei Liu*, 2023: Climatological spatial scales of meteorological droughts in China and associated climate variability. <em>Journal of Hydrology<\/em>, 617, 129056. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0022169422016262\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenchen Liu, and <strong>Wen Zhou*<\/strong>, 2023: Global Seasonal-Scale Meteorological Droughts. Part II: Temperature Anomaly-Based Classifications. <em>Ocean-Land-Atmosphere Research<\/em>, 2, 0017. <a href=\"https:\/\/spj.science.org\/doi\/abs\/10.34133\/olar.0017\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenchen Liu, and <strong>Wen Zhou*<\/strong>, 2023: Global Seasonal-Scale Meteorological Droughts. Part I: Detection, Metrics, and Inland\/Coastal Types. <em>Ocean-Land-Atmosphere Research<\/em>, 2, 0016. <a href=\"https:\/\/spj.science.org\/doi\/abs\/10.34133\/olar.0016\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ruhua Zhang, <strong>Wen Zhou*<\/strong>, Wenshou Tian, Yue Zhang, Yuntao Jian, and Yana Li, 2023: Tropical Stratospheric Forcings Weaken the Response of the East Asian Winter Temperature to ENSO. <em>Ocean-Land-Atmosphere Research<\/em>, 2, 0001. <a href=\"https:\/\/spj.science.org\/doi\/abs\/10.34133\/olar.0001\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang, and <strong>Wen Zhou*<\/strong>, 2023: Impact of Saharan dust on landfalling North Atlantic tropical cyclones over North America in September. <em>Atmospheric and Oceanic Science Letters<\/em>, 16, 100276. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283422001581\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang, and <strong>Wen Zhou*<\/strong>, 2023: Oceanic thermal forcing of North Atlantic tropical cyclones. <em>Atmospheric and Oceanic Science Letters<\/em>, 16, 100286. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283422001696\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2022<\/h3><p>Oluwafemi E. 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Zhang, 2022: An Extreme Drought over South China in 2020\/21 Concurrent with an Unprecedented Warm Northwest Pacific and La Ni\u00f1a. <em>Advances in Atmospheric Sciences<\/em>, 39, 1637-1649. <a href=\"https:\/\/doi.org\/10.1007\/s00376-022-1456-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yue Zhang, <strong>Wen Zhou*,<\/strong> Jian Ling, and Lixin Qi, 2022: Water Vapor Transport by an Equivalent-Barotropic Cyclonic Anomaly Corresponding to Extreme Austral Late Summer Precipitation in Southeast Australia during 2021. <em>Journal of the Atmospheric Sciences<\/em>, 79, 2343-2361. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/atsc\/79\/9\/JAS-D-21-0267.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenchen Liu, <strong>Wen Zhou*<\/strong>, Ruhua Zhang, Yue Zhang, and Ya Wang, 2022: Global-Scale Interpretable Drought Reconstruction Utilizing Anomalies of Atmospheric Dynamics. <em>Journal of Hydrometeorology<\/em>, 23, 1507-1524. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/hydr\/23\/9\/JHM-D-22-0006.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ruhua Zhang, <strong>Wen Zhou*<\/strong>, Wenshou Tian, Yue Zhang, Zhenchen Liu, and Paxson K. 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Cheung, 2022: Changes in the Relationship between ENSO and the Winter Arctic Stratospheric Polar Vortex in Recent Decades. <em>Journal of Climate<\/em>, 35, 5399-5414. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/35\/16\/JCLI-D-21-0924.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiaocheng Yu, <strong>Wen Zhou*<\/strong>, and Yue Zhang, 2022: The decadal shift in TC-induced precipitation over China. <em>Atmospheric Research<\/em>, 274, 106186. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0169809522001727\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ho-Nam Cheung*, Noel Keenlyside, Torben Koenigk, Shuting Yang, Tian Tian, Zhiqing Xu, Yongqi Gao, Fumiaki Ogawa, Nour-Eddine Omrani, Shaobo Qiao, and <strong>Wen Zhou*<\/strong>, 2022: Assessing the influence of sea surface temperature and arctic sea ice cover on the uncertainty in the boreal winter future climate projections. <em>Climate Dynamics<\/em>, 59, 433-454. <a href=\"https:\/\/doi.org\/10.1007\/s00382-022-06136-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y.-T. Leung, Dongxiao Wang, <strong>Wen Zhou*<\/strong>, Yue Zhang, and Lin Wang, 2022: Interdecadal Variation in Available Potential Energy of Stationary Eddies in the Midlatitude Northern Hemisphere in Response to the North Pacific Gyre Oscillation. <em>Geophysical Research Letters<\/em>, 49, e2022GL098297. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2022GL098297\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p style=\"font-weight: 400;\">Yue Zhang, <strong>Wen Zhou*<\/strong>, Xin Wang, Sheng Chen, Jiepeng Chen, and Shanshan Li, 2022: Indian Ocean Dipole and ENSO\u2019s mechanistic importance in modulating the ensuing-summer precipitation over Eastern China. <em><i>npj Climate and Atmospheric Science<\/i><\/em>, 5, 48.\u00a0<a href=\"https:\/\/doi.org\/10.1038\/s41612-022-00271-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, Dongxiao Wang, <strong>Wen Zhou*<\/strong>, Paxson K. Y. Cheung, Yuntao Jian, and Fuan Xiao, 2022: Joint Effect of West Pacific Warming and the Arctic Oscillation on the Bidecadal Variation and Trend of the East Asian Trough. <em>Journal of Climate<\/em>, 35, 2491-2501. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/35\/8\/JCLI-D-21-0461.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Chong-wei Zheng*, Di Wu, Hai-lang Wu, Jing Guo, Chong Shen, Chuan Tian, Xin-long Tian, Zi-niu Xiao, <strong>\u5468\u6587<\/strong>, and Chong-yin Li, 2022: Propagation and attenuation of swell energy in the Pacific Ocean. <em>Renewable Energy<\/em>, 188, 750-764. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0960148122002130\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>E. Adeyeri*, P. Laux, K. A. Ishola, <strong>\u5468\u6587<\/strong>, I. A. Balogun, Z. D. Adeyewa, and H. Kunstmann, 2022: Homogenising meteorological variables: Impact on trends and associated climate indices. <em>Journal of Hydrology<\/em>, 607, 127585. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0022169422001603\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Shifei Tu, Johnny C. L. Chan*, Jianjun Xu*, and <strong>\u5468\u6587<\/strong>, 2022: Opposite Changes in Tropical Cyclone Rain Rate During the Recent El Ni\u00f1o and La Ni\u00f1a Years. <em>Geophysical Research Letters<\/em>, 49, e2021GL097412. <a href=\"https:\/\/doi.org\/10.1029\/2021GL097412\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Chong-wei Zheng*, Cheng-tao Yi, Chong Shen, De-chuan Yu, Xiao-lu Wang, Yong Wang, Wen-kai Zhang, Yong Wei, Yun-ge Chen, Wei Li, Xin Jin, Shuai-dong Jia, Di Wu, Ding-jiang Wei, Xiao-feng Zhao, Yan-yan Tian, <strong>\u5468\u6587<\/strong>, and Zi-niu Xiao, 2022: A Positive Climatic Trend in the Global Offshore Wind Power. <em>Frontiers in Energy Research<\/em>, 10. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/fenrg.2022.867642\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang*, Cong Zhang, and <strong>\u5468\u6587<\/strong>, 2022: Association between tropospheric temperature and tropical cyclone peak intensity over the North Pacific and North Atlantic. <em>Atmospheric and Oceanic Science Letters<\/em>, 15, 100117. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283421000969\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>A. E. Lakshani, <strong>Wen Zhou*<\/strong>, and Paxson K. Y. Cheung, 2022: Impacts of El Ni\u00f1o Diversity on Tropical Cyclone Activity in the Bay of Bengal. <em>Frontiers in Earth Science<\/em>, 10. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/feart.2022.824769\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ye Tian, <strong>Wen Zhou*<\/strong>, and W. K. Wong, 2022: Detecting Interdecadal Change in Western North Pacific Tropical Cyclone Genesis Based on Cluster Analysis Using pHash + Kmeans. <em>Frontiers in Earth Science<\/em>, 9. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/feart.2021.825835\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Paxson K. Y. Cheung, <strong>Wen Zhou*<\/strong>, Dongxiao Wang, and Marco Y. T. Leung, 2022: Dissimilarity among Ocean Reanalyses in Equatorial Pacific Upper-Ocean Heat Content and Its Relationship with ENSO. <em>Advances in Atmospheric Sciences<\/em>, 39, 67-79. <a href=\"https:\/\/doi.org\/10.1007\/s00376-021-1109-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>\u00a0<\/h3><h3>2021<\/h3><p>Yuntao Jian, Marco Y. T. Leung, <strong>Wen Zhou*<\/strong>, Maoqiu Jian, and Song Yang, 2021: Present and Future Relations between ENSO and Winter Synoptic Temperature Variability over the Asian\u2013Pacific\u2013American Region Simulated by CMIP5\/6. <em>Journal of Climate<\/em>, 34, 9899-9913. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/34\/24\/JCLI-D-21-0210.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Shuai-Lei Yao*, <strong>Wen Zhou*<\/strong>, Fei-Fei Jin, and Fei Zheng, 2021: North Atlantic as a Trigger for Pacific-Wide Decadal Climate Change. <em>Geophysical Research Letters<\/em>, 48, e2021GL094719. <a href=\"https:\/\/doi.org\/10.1029\/2021GL094719\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenchen Liu, and <strong>Wen Zhou*<\/strong>, 2021: The 2019 Autumn Hot Drought Over the Middle-Lower Reaches of the Yangtze River in China: Early Propagation, Process Evolution, and Concurrence. <em>Journal of Geophysical Research: Atmospheres<\/em>, 126, e2020JD033742. <a href=\"https:\/\/doi.org\/10.1029\/2020JD033742\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Paxson K. Y. Cheung, Marco Y. T. Leung, and <strong>Wen Zhou*<\/strong>, 2021: Position, Magnitude, and Size of Warm-Pool El Ni\u00f1o: Variability, Seasonal Predictability, and Climate Impacts. <em>Journal of Geophysical Research: Atmospheres<\/em>, 126, e2021JD034917. <a href=\"https:\/\/doi.org\/10.1029\/2021JD034917\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuntao Jian, Marco Y. T. Leung, <strong>Wen Zhou*<\/strong>, Maoqiu Jian, Song Yang, and Xiaoxia Lin, 2021: Interdecadal Shift of the Relationship between ENSO and Winter Synoptic Temperature Variability over the Asian\u2013Pacific\u2013American Region in the 1980s. <em>Journal of Climate<\/em>, 34, 5321-5335. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/34\/13\/JCLI-D-20-0931.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Gang Li, <strong>Wen Zhou*<\/strong>, Yue Zhang, and Hongming Yan, 2021: Spatiotemporal characteristics of spring rainfall over Southwest China and their relationships with sea surface temperature during 1961\u20132017. <em>Theoretical and Applied Climatology<\/em>, 145, 775-786. <a href=\"https:\/\/doi.org\/10.1007\/s00704-021-03648-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiaochi Huang, Han Zhou, Xiaofeng Yang, <strong>Wen Zhou*<\/strong>, Jiejun Huang, and Yanbin Yuan, 2021: Spatial Characteristics of Coronavirus Disease 2019 and Their Possible Relationship With Environmental and Meteorological Factors in Hubei Province, China. <em>GeoHealth<\/em>, 5, e2020GH000358. <a href=\"https:\/\/doi.org\/10.1029\/2020GH000358\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang*, Bingyin Chen, Yong Xu, <strong>\u5468\u6587<\/strong>, and Xuemei Wang, 2021: Urban heat islands in Hong Kong: Bonding with atmospheric stability. <em>Atmospheric Science Letters<\/em>, 22, e1032. <a href=\"https:\/\/doi.org\/10.1002\/asl.1032\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang*, and <strong>\u5468\u6587<\/strong>, 2021: Influence of dust aerosols on eastern Pacific tropical cyclone intensity. <em>Atmospheric and Oceanic Science Letters<\/em>, 14, 100028. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1674283420300283\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Han Zhou, Xiaochi Huang, <strong>Wen Zhou*<\/strong>, Yue Zhang, and Yong Liu, 2021: Spatial correlation length of summer extreme heat stress over eastern China. <em>International Journal of Climatology<\/em>, 41, 3121-3138. <a href=\"https:\/\/doi.org\/10.1002\/joc.7009\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yue Zhang, <strong>Wen Zhou*<\/strong>, and Tim Li, 2021: Impact of the Indian Ocean Dipole on Evolution of the Subsequent ENSO: Relative Roles of Dynamic and Thermodynamic Processes. <em>Journal of Climate<\/em>, 34, 3591-3607. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/34\/9\/JCLI-D-20-0487.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yana Li, Ho-Nam Cheung*, and <strong>\u5468\u6587<\/strong>, 2021: Asymmetric Relationship Between Mid-latitude Eurasian Circulation and Summer Rainfall in Hong Kong in Different Phases of ENSO. <em>Frontiers in Earth Science<\/em>, 9. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/feart.2021.642588\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><\/div>\n\t\t\t\t\t\t\t\t\t<div class=\"elementor-tab-title elementor-tab-mobile-title\" aria-selected=\"false\" data-tab=\"3\" role=\"tab\" tabindex=\"-1\" aria-controls=\"elementor-tab-content-1123\" aria-expanded=\"false\">2020-2016<\/div>\n\t\t\t\t\t<div id=\"elementor-tab-content-1123\" class=\"elementor-tab-content elementor-clearfix\" data-tab=\"3\" role=\"tabpanel\" aria-labelledby=\"elementor-tab-title-1123\" tabindex=\"0\" hidden=\"hidden\"><h3>2020<\/h3><p>Han Zhou, <strong>\u5468\u6587<\/strong>, Yuanbo Liu*, Yanbin Yuan, Jiejun Huang, and Yongwei Liu, 2020: Identifying spatial extent of meteorological droughts: An examination over a humid region. <em>Journal of Hydrology<\/em>, 591, 125505. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0022169420309653\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintomide Afolayan Akinsanola, <strong>Wen Zhou*<\/strong>, Tianjun Zhou, and Noel Keenlyside, 2020: Amplification of synoptic to annual variability of West African summer monsoon rainfall under global warming. <em>npj Climate and Atmospheric Science<\/em>, 3, 21. <a href=\"https:\/\/doi.org\/10.1038\/s41612-020-0125-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Chao He, and <strong>Wen Zhou*<\/strong>, 2020: Different Enhancement of the East Asian Summer Monsoon under Global Warming and Interglacial Epochs Simulated by CMIP6 Models: Role of the Subtropical High. <em>Journal of Climate<\/em>, 33, 9721-9733. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/22\/jcliD200304.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Chao He, Tim Li, and <strong>Wen Zhou*<\/strong>, 2020: Drier North American Monsoon in Contrast to Asian\u2013African Monsoon under Global Warming. <em>Journal of Climate<\/em>, 33, 9801-9816. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/22\/jcliD200189.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuntao Jian, Xiaoxia Lin, <strong>\u5468\u6587<\/strong>, Maoqiu Jian*, Marco Y. T. Leung, and Paxson K. Y. Cheung, 2020: Analysis of Record-High Temperature over Southeast Coastal China in Winter 2018\/19: The Combined Effect of Mid- to High-Latitude Circulation Systems and SST Forcing over the North Atlantic and Tropical Western Pacific. <em>Journal of Climate<\/em>, 33, 8813-8831. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/20\/jcliD190732.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, <strong>Wen Zhou*<\/strong>, Dongxiao Wang, P. W. Chan, S. M. Lee, and H. W. Tong, 2020: Remote Tropical Western Indian Ocean Forcing on Changes in June Precipitation in South China and the Indochina Peninsula. <em>Journal of Climate<\/em>, 33, 7553-7566. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/17\/jcliD190626.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yong Liu*, <strong>\u5468\u6587<\/strong>, Xia Qu, and Renguang Wu, 2020: An Interdecadal Change of the Boreal Summer Silk Road Pattern around the Late 1990s. <em>Journal of Climate<\/em>, 33, 7083-7100. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/33\/16\/JCLI-D-19-0795.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>YaJun Shi, Yan Du*, Zesheng Chen, and <strong>\u5468\u6587<\/strong>, 2019: Occurrence and impacts of tropical cyclones over the southern South China Sea. <em>International Journal of Climatology<\/em>, 40, 4218 \u2013 4227.<a href=\"https:\/\/doi.org\/10.1002\/joc.6454\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo T. Abolude*, <strong>\u5468\u6587<\/strong>, and Akintomide A. Akinsanola, 2020: Evaluation and Projections of Wind Power Resources over China for the Energy Industry Using CMIP5 Models. <em>Energies<\/em>, 13, 2417. <a href=\"https:\/\/doi.org\/10.3390\/en13102417\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintomide A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2020: Understanding the Variability of West African Summer Monsoon Rainfall: Contrasting Tropospheric Features and Monsoon Index. <em>Atmosphere,<\/em> 11, 309. <a href=\"https:\/\/doi.org\/10.3390\/atmos11030309\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Shaobo Qiao, Meng Zou, Ho Nam Cheung*, <strong>\u5468\u6587<\/strong>, Qingxiang Li, Guolin Feng, and Wenjie Dong*, 2020: Predictability of the wintertime 500\u00a0hPa geopotential height over Ural-Siberia in the NCEP climate forecast system. <em>Climate Dynamics<\/em>, 54, 1591-1606. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-05074-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Han Zhou, <strong>\u5468\u6587<\/strong>, Yuanbo Liu*, Yanbin Yuan, Jiejun Huang, and Yongwei Liu, 2020: Meteorological Drought Migration in the Poyang Lake Basin, China: Switching among Different Climate Modes. <em>Journal of Hydrometeorology<\/em>, 21, 415-431. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/hydr\/21\/3\/jhm-d-19-0183.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2019<\/h3><p>Yue Zhang, <strong>Wen Zhou*<\/strong>, Eric C. H. Chow, and Marco Y. T. Leung, 2019: Delayed impacts of the IOD: cross-seasonal relationships between the IOD, Tibetan Plateau snow, and summer precipitation over the Yangtze\u2013Huaihe River region. <em>Climate Dynamics<\/em>, 53, 4077-4093. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-04774-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yana Li, Song Yang*, Yi Deng, Xiaoming Hu, Ming Cai, and <strong>\u5468\u6587<\/strong>, 2019: Detection and attribution of upper-tropospheric warming over the tropical western Pacific. <em>Climate Dynamics<\/em>, 53, 3057-3068. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-04681-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Fuan Xiao, Dongxiao Wang, Lili Zeng*, Qin-Yan Liu, and <strong>\u5468\u6587<\/strong>, 2019: Contrasting changes in the sea surface temperature and upper ocean heat content in the South China Sea during recent decades. <em>Climate Dynamics<\/em>, 53, 1597-1612. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-04697-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, <strong>Wen Zhou*<\/strong>, K. Y. Cheung, H. N. Gong, and Y. Zhang, 2019: Enhancement of lower tropospheric winter synoptic temperature variations in Southwest China and the northern Indochina Peninsula after 2010. <em>Climate Dynamics<\/em>, 53, 2281-2294. <a href=\"https:\/\/doi.org\/10.1007\/s00382-019-04841-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hainan Gong, Lin Wang*, Wen Chen, Renguang Wu, <strong>\u5468\u6587<\/strong>, Lin Liu, Debashis Nath, and Xiaoqing Lan, 2019: Diversity of the Wintertime Arctic Oscillation Pattern among CMIP5 Models: Role of the Stratospheric Polar Vortex. <em>Journal of Climate<\/em>, 32, 5235-5250. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/32\/16\/jcli-d-18-0603.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2019: Projection of West African summer monsoon rainfall in dynamically downscaled CMIP5 models. <em>Climate Dynamics<\/em>, 53, 81-95. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4568-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Eric C. H. Chow, Min Wen, Lei Li, Marco Y. T. Leung, Paxson K. Y. Cheung, and <strong>Wen Zhou*<\/strong>, 2019: Assessment of the Environmental and Societal Impacts of the Category-3 Typhoon Hato. <em>Atmosphere,<\/em> 10, 296. <a href=\"https:\/\/doi.org\/10.3390\/atmos10060296\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Wei Wei*, Yuting Wu, Song Yang, and <strong>\u5468\u6587<\/strong>, 2019: Role of the South Asian High in the Onset Process of the Asian Summer Monsoon during Spring-to-Summer Transition. <em>Atmosphere,<\/em> 10, 239. <a href=\"https:\/\/doi.org\/10.3390\/atmos10050239\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yue Zhang, <strong>Wen Zhou*<\/strong>, and Marco Y. T. Leung, 2019: Phase relationship between summer and winter monsoons over the South China Sea: Indian Ocean and ENSO forcing. <em>Climate Dynamics<\/em>, 52, 5229-5248. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4440-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2019: Ensemble-based CMIP5 simulations of West African summer monsoon rainfall: current climate and future changes. <em>Theoretical and Applied Climatology<\/em>, 136, 1021-1031. <a href=\"https:\/\/doi.org\/10.1007\/s00704-018-2516-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2019: Dynamic and thermodynamic factors controlling increasing summer monsoon rainfall over the West African Sahel. <em>Climate Dynamics<\/em>, 52, 4501-4514. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4394-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Shuang Qiu, and <strong>Wen Zhou*<\/strong>, 2019: Variation in Summer Rainfall over the Yangtze River Region during Warming and Hiatus Periods. <em>Atmosphere<\/em>, 10, 173. <a href=\"https:\/\/doi.org\/10.3390\/atmos10040173\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hainan Gong, <strong>Wen Zhou*<\/strong>, Wen Chen, Lin Wang, Marco Y. T. Leung, Paxson K. Y. Cheung, and Yue Zhang, 2019: Modulation of the southern Indian Ocean dipole on the impact of El Ni\u00f1o\u2013Southern Oscillation on Australian summer rainfall. <em>International Journal of Climatology<\/em>, 39, 2484-2490. <a href=\"https:\/\/doi.org\/10.1002\/joc.5941\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>A. Akinsanola, and <strong>Wen Zhou*<\/strong>, 2019: Projections of West African summer monsoon rainfall extremes from two CORDEX models. <em>Climate Dynamics<\/em>, 52, 2017-2028. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4238-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang*, <strong>\u5468\u6587<\/strong>, and Liangui Yang, 2019: Analysis of dust wet deposition in the mid-latitudes of the Northern Hemisphere. <em>Air Quality, Atmosphere &amp; Health<\/em>, 12, 217-227. <a href=\"https:\/\/doi.org\/10.1007\/s11869-018-0652-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo T. Abolude, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2019: A Comparative Computational Fluid Dynamic Study on the Effects of Terrain Type on Hub-Height Wind Aerodynamic Properties. <em>Energies<\/em>, 12, 83. <a href=\"https:\/\/www.mdpi.com\/1996-1073\/12\/1\/83\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2018<\/h3><p>Marco Y. T. Leung, Shuang Qiu, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Modulations of rising motion and moisture on summer precipitation over the middle and lower reaches of the Yangtze river. <em>Climate Dynamics<\/em>, 51, 4259-4269. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4247-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hainan Gong, Lin Wang, <strong>\u5468\u6587<\/strong>, Wen Chen*, Renguang Wu, Lin Liu, Debashis Nath, and Marco Y. T. Leung, 2018: Revisiting the Northern Mode of East Asian Winter Monsoon Variation and Its Response to Global Warming. <em>Journal of Climate<\/em>, 31, 9001-9014. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-18-0136.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Gang Huang*, Wen Chen, <strong>\u5468\u6587<\/strong>, and Weiqiang Wang, 2018: Wet-to-dry shift over Southwest China in 1994 tied to the warming of tropical warm pool. <em>Climate Dynamics<\/em>, 51, 3111-3123. <a href=\"https:\/\/doi.org\/10.1007\/s00382-018-4068-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jiepeng Chen, Xin Wang*, <strong>\u5468\u6587<\/strong>, Chunzai Wang, Qiang Xie, Gang Li, and Sheng Chen, 2018: Unusual Rainfall in Southern China in Decaying August during Extreme El Ni\u00f1o 2015\/16: Role of the Western Indian Ocean and North Tropical Atlantic SST. <em>Journal of Climate<\/em>, 31, 7019-7034. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-17-0827.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Eric C. H. Chow, Richard C. Y. Li, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Influence of Tropical Cyclones on Hong Kong Air Quality. <em>Advances in Atmospheric Sciences<\/em>, 35, 1177-1188. <a href=\"https:\/\/doi.org\/10.1007\/s00376-018-7225-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jiepeng Chen, Xin Wang*, <strong>\u5468\u6587<\/strong>, and Zhiping Wen, 2018: Interdecadal change in the summer SST-precipitation relationship around the late 1990s over the South China Sea. <em>Climate Dynamics<\/em>, 51, 2229-2246. <a href=\"https:\/\/doi.org\/10.1007\/s00382-017-4009-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo Temiloluwa Abolude, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Assessment and Performance Evaluation of a Wind Turbine Power Output. <em>Energies<\/em>, 11, 1992. <a href=\"https:\/\/www.mdpi.com\/1996-1073\/11\/8\/1992\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Circumglobal teleconnection and eddy control of variation in summer precipitation over Northwest China. <em>Climate Dynamics<\/em>, 51, 1351-1362. <a href=\"https:\/\/doi.org\/10.1007\/s00382-017-3958-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Cheng Qian*, <strong>\u5468\u6587<\/strong>, Xiu-Qun Yang, and Johnny C. L. Chan, 2018: Statistical prediction of non-Gaussian climate extremes in urban areas based on the first-order difference method. <em>International Journal of Climatology<\/em>, 38, 2889-2898. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/joc.5464\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Chi-Ming Shun, and Pak-Wai Chan, 2018: Large-scale Circulation Control of the Occurrence of Low-level Turbulence at Hong Kong International Airport. <em>Advances in Atmospheric Sciences<\/em>, 35, 435-444. <a href=\"https:\/\/doi.org\/10.1007\/s00376-017-7118-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2018: Revisiting the intraseasonal, interannual and interdecadal variability of tropical cyclones in the western North Pacific. <em>Atmospheric and Oceanic Science Letters<\/em>, 11, 198-208. <a href=\"https:\/\/doi.org\/10.1080\/16742834.2018.1459460\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung*, Noel Keenlyside, Nour-Eddine Omrani, and <strong>\u5468\u6587<\/strong>, 2018: Remarkable link between projected uncertainties of Arctic sea-ice decline and winter Eurasian climate. <em>Advances in Atmospheric Sciences<\/em>, 35, 38-51. <a href=\"https:\/\/doi.org\/10.1007\/s00376-017-7156-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Gang Li, Jiepeng Chen, Xin Wang*, Xia Luo, Daoyong Yang, <strong>\u5468\u6587<\/strong>, Yanke Tan, and Hongming Yan, 2018: Remote impact of North Atlantic sea surface temperature on rainfall in southwestern China during boreal spring. <em>Climate Dynamics<\/em>, 50, 541-553. <a href=\"https:\/\/doi.org\/10.1007\/s00382-017-3625-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Fuan Xiao, Lili Zeng, Qin-Yan Liu, <strong>\u5468\u6587<\/strong>, and Dongxiao Wang*, 2018: Extreme subsurface warm events in the South China Sea during 1998\/99 and 2006\/07: observations and mechanisms. <em>Climate Dynamics<\/em>, 50, 115-128. <a href=\"https:\/\/doi.org\/10.1007\/s00382-017-3588-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2017<\/h3><p>Shuang Qiu, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Marco Yu-Ting Leung, and Xiuzhen Li, 2017: Regional moisture budget associated with drought\/flood events over China. <em>Progress in Earth and Planetary Science<\/em>, 4, 36. <a href=\"https:\/\/doi.org\/10.1186\/s40645-017-0148-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo T. Abolude, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, and Yu Ting Leung, 2017: Regional Impact Assessment of Monsoon Variability on Wind Power Availability and Optimization in Asia. <em>Atmosphere<\/em>, 8, 219. <a href=\"https:\/\/www.mdpi.com\/2073-4433\/8\/11\/219\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2017: Impact of Arctic amplification on East Asian winter climate. <em>Atmospheric and Oceanic Science Letters<\/em>, 10, 385-388. <a href=\"https:\/\/doi.org\/10.1080\/16742834.2017.1350093\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiaobin Lin, Zhiping Wen, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Renguang Wu, and Ruidan Chen, 2017: Effects of tropical cyclone activity on the boundary moisture budget over the eastern China monsoon region. <em>Advances in Atmospheric Sciences<\/em>, 34, 700-712. <a href=\"https:\/\/doi.org\/10.1007\/s00376-017-6191-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, C. M. Shun, and Tsz Cheung Lee, 2017: Change in Destructiveness of Landfalling Tropical Cyclones over China in Recent Decades. <em>Journal of Climate<\/em>, 30, 3367-3379. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-16-0258.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang, <strong>\u5468\u6587<\/strong>, Mark Wenig, and Liangui Yang*, 2017: Impact of long-range desert dust transport on coastal East Asia: analysis of urban dust concentration and wet deposition with model simulation. <em>Air Quality, Atmosphere &amp; Health<\/em>, 10, 325-337. <a href=\"https:\/\/doi.org\/10.1007\/s11869-016-0440-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2017: Statistical modeling and trend detection of extreme sea level records in the Pearl River Estuary. <em>Advances in Atmospheric Sciences<\/em>, 34, 383-396. <a href=\"https:\/\/doi.org\/10.1007\/s00376-016-6041-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Akintayo Abolude*, and <strong>\u5468\u6587<\/strong>, 2017: A preliminary analysis of wind turbine energy yield. <em>Energy Procedia<\/em>, 138, 423-428. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1876610217351329\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, Yongqin David Chen*, and <strong>\u5468\u6587<\/strong>, 2017: Response of Winter Moisture Circulation to the India\u2013Burma Trough and Its Modulation by the South Asian Waveguide. <em>Journal of Climate<\/em>, 30, 1197-1210. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-16-0111.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang, <strong>\u5468\u6587<\/strong>, Mark Wenig, and Liangui Yang*, 2017: Impact of long-range desert dust transport on hydrometeor formation over coastal East Asia. <em>Advances in Atmospheric Sciences<\/em>, 34, 101-115. <a href=\"https:\/\/doi.org\/10.1007\/s00376-016-6157-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong><strong>*<\/strong>, Richard C. Y. Li, and Eric C. H. Chow, 2017: Intraseasonal variation of visibility in Hong Kong. <em>Advances in Atmospheric Sciences<\/em>, 34, 26-38. <a href=\"https:\/\/doi.org\/10.1007\/s00376-016-6056-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, Hoffman H. N. Cheung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2017: Meridional displacement of the East Asian trough and its response to the ENSO forcing. <em>Climate Dynamics<\/em>, 48, 335-352. <a href=\"https:\/\/doi.org\/10.1007\/s00382-016-3077-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2016<\/h3><p>Hoffman H. N. Cheung, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Marco Y. T. Leung, C. M. Shun, S. M. Lee, and H. W. Tong, 2016: A strong phase reversal of the Arctic Oscillation in midwinter 2015\/2016: Role of the stratospheric polar vortex and tropospheric blocking. <em>Journal of Geophysical Research: Atmospheres<\/em>, 121, 13, 443-413, 457. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/2016JD025288\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Y. T. Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2016: Direct and indirect ENSO modulation of winter temperature over the Asian\u2013Pacific\u2013American region. <em>Scientific Reports<\/em>, 6, 36356. <a href=\"https:\/\/doi.org\/10.1038\/srep36356\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Edward Yan Yung Ng, and Yong Xu, 2016: Urban heat islands in Hong Kong: statistical modeling and trend detection. <em>Natural Hazards<\/em>, 83, 885-907. <a href=\"https:\/\/doi.org\/10.1007\/s11069-016-2353-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Yu-Ting Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2016: Eddy contributions at multiple timescales to the evolution of persistent anomalous East Asian trough. <em>Climate Dynamics<\/em>, 46, 2287-2303. <a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2702-2\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2016: Simple metrics for representing East Asian winter monsoon variability: Urals blocking and western Pacific teleconnection patterns. <em>Advances in Atmospheric Sciences<\/em>, 33, 695-705. <a href=\"https:\/\/doi.org\/10.1007\/s00376-015-5204-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Xiuzhen Li, Xin Wang, and Dongxiao Wang, 2016: Synoptic-scale characteristics and atmospheric controls of summer heat waves in China. <em>Climate Dynamics<\/em>, 46, 2923-2941.<a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2741-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Gang Huang*, <strong>\u5468\u6587<\/strong>, and Wen Chen, 2016: Historical change and future scenarios of sea level rise in Macau and adjacent waters. <em>Advances in Atmospheric Sciences<\/em>, 33, 462-475. <a href=\"https:\/\/doi.org\/10.1007\/s00376-015-5047-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, and Yongqin David Chen, 2016: Detecting the origins of moisture over southeast China: Seasonal variation and heavy rainfall. <em>Advances in Atmospheric Sciences<\/em>, 33, 319-329. <a href=\"https:\/\/doi.org\/10.1007\/s00376-015-4197-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Tao Feng, Xiu-Qun Yang*, <strong>\u5468\u6587<\/strong>, Ronghui Huang, Liang Wu, and Dejian Yang, 2016: Synoptic-Scale Waves in Sheared Background Flow over the Western North Pacific. <em>Journal of the Atmospheric Sciences<\/em>, 73, 4583-4603. <a href=\"https:\/\/doi.org\/10.1175\/JAS-D-16-0064.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Wen Chen*, <strong>\u5468\u6587<\/strong>, and Gang Huang, 2016: Understanding and detecting super-extreme droughts in Southwest China through an integrated approach and index. <em>Quarterly Journal of the Royal Meteorological Society<\/em>, 142, 529-535. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/qj.2593\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Li Xiuzhen, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2016: Modulation of the interannual variation of the India-Burma Trough on the winter moisture supply over Southwest China. <em>Climate Dynamics<\/em>, 46, 147-158. <a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2575-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><\/div>\n\t\t\t\t\t\t\t\t\t<div class=\"elementor-tab-title elementor-tab-mobile-title\" aria-selected=\"false\" data-tab=\"4\" role=\"tab\" tabindex=\"-1\" aria-controls=\"elementor-tab-content-1124\" aria-expanded=\"false\">2015-2011<\/div>\n\t\t\t\t\t<div id=\"elementor-tab-content-1124\" class=\"elementor-tab-content elementor-clearfix\" data-tab=\"4\" role=\"tabpanel\" aria-labelledby=\"elementor-tab-title-1124\" tabindex=\"0\" hidden=\"hidden\"><h3>2015<\/h3><p>Lin Wang, Wen Chen*, <strong>\u5468\u6587<\/strong>, and Gang Huang, 2015: Teleconnected influence of tropical Northwest Pacific sea surface temperature on interannual variability of autumn precipitation in Southwest China. <em>Climate Dynamics<\/em>, 45, 2527-2539. <a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2490-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Yu-Ting Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2015: Variation of circulation and East Asian climate associated with anomalous strength and displacement of the East Asian trough. <em>Climate Dynamics<\/em>, 45, 2713-2732. <a href=\"https:\/\/doi.org\/10.1007\/s00382-015-2504-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jiangjiang Xia*, Zhongwei Yan, <strong>\u5468\u6587<\/strong>, Soi Kun Fong, Ka Cheng Leong, Iu Man Tang, S. W. Chang, W. K. Leong, and Shaofei Jin, 2015: Projection of the Zhujiang (Pearl) River Delta\u2019s potential submerged area due to sea level rise during the 21st century based on CMIP5 simulations. <em>Acta Oceanologica Sinica<\/em>, 34, 78-84. <a href=\"https:\/\/doi.org\/10.1007\/s13131-015-0700-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, and Yongqin David Chen, 2015: Assessment of Regional Drought Trend and Risk over China: A Drought Climate Division Perspective. <em>Journal of Climate<\/em>, 28, 7025-7037. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00403.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Yu-Ting Leung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2015: Vertical structure, physical properties, and energy exchange of the East Asian trough in boreal winter. <em>Climate Dynamics<\/em>, 45, 1635-1656. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2419-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2015: Multiscale control of summertime persistent heavy precipitation events over South China in association with synoptic, intraseasonal, and low-frequency background. <em>Climate Dynamics<\/em>, 45, 1043-1057. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2347-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jiangjiang Xia*, Zhongwei Yan, Gensuo Jia, Heqing Zeng, Philip Douglas Jones, <strong>\u5468\u6587<\/strong>, and Anzhi Zhang, 2015: Projections of the advance in the start of the growing season during the 21st century based on CMIP5 simulations. <em>Advances in Atmospheric Sciences<\/em>, 32, 831-838. <a href=\"https:\/\/doi.org\/10.1007\/s00376-014-4125-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong><strong>*<\/strong>, Yun Li, Xin Wang, and Dongxiao Wang, 2015: Statistical modeling and CMIP5 simulations of hot spell changes in China. <em>Climate Dynamics<\/em>, 44, 2859-2872. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2287-1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Kun-Hui Ye, Chi-Yung Tam*, <strong>\u5468\u6587<\/strong>, and Soo-Jin Sohn, 2015: Seasonal prediction of June rainfall over South China: Model assessment and statistical downscaling. <em>Advances in Atmospheric Sciences<\/em>, 32, 680-689. <a href=\"https:\/\/doi.org\/10.1007\/s00376-014-4047-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Marco Yu-Ting Leung, Hoffman Ho-Nam Cheung, and <strong>\u5468\u6587<\/strong><strong>*<\/strong>, 2015: Energetics and dynamics associated with two typical mobile trough pathways over East Asia in boreal winter. <em>Climate Dynamics<\/em>, 44, 1611-1626. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2355-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang*, Wen Chen, <strong>\u5468\u6587<\/strong>, and Gang Huang, 2015: Drought in Southwest China: A Review. <em>Atmos. Oceanic Sci. Lett.<\/em>, 102. <a href=\"https:\/\/doi.org\/10.3878\/AOSL20150043\">[\u8bba\u6587\u4e3b\u9875]<\/a>.<\/p><p>Hoffman H. N. Cheung, and <strong>\u5468\u6587<\/strong>*, 2015: Implications of Ural Blocking for East Asian Winter Climate in CMIP5 GCMs. Part I: Biases in the Historical Scenario. <em>Journal of Climate<\/em>, 28, 2203-2216. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00308.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, and <strong>\u5468\u6587<\/strong>*, 2015: Implications of Ural Blocking for East Asian Winter Climate in CMIP5 GCMs. Part II: Projection and Uncertainty in Future Climate Conditions. <em>Journal of Climate<\/em>, 28, 2217-2233. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00309.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, <strong>\u5468\u6587<\/strong>*, Sai-ming Lee, and Hang-wai Tong, 2015: Interannual and Interdecadal Variability of the Number of Cold Days in Hong Kong and Their Relationship with Large-Scale Circulation. <em>Monthly Weather Review<\/em>, 143, 1438-1454. <a href=\"https:\/\/doi.org\/10.1175\/MWR-D-14-00335.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong>*, Soi Kun Fong, Ka Cheng Leong, Iu Man Tang, Sau Wa Chang, and Weng Kun Leong, 2015: Extreme rainfall and summer heat waves in Macau based on statistical theory of extreme values. <em>Climate Reseach<\/em>, 66:91-101. <a href=\"https:\/\/doi.org\/10.3354\/cr01336\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, <strong>\u5468\u6587<\/strong>*, and Tsz Cheung Lee, 2015: Climatological Characteristics and Observed Trends of Tropical Cyclone\u2013Induced Rainfall and Their Influences on Long-Term Rainfall Variations in Hong Kong. <em>Monthly Weather Review<\/em>, 143, 2192-2206. <a href=\"https:\/\/doi.org\/10.1175\/MWR-D-14-00332.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2015: Interdecadal Changes in Summertime Tropical Cyclone Precipitation over Southeast China during 1960\u20132009. <em>Journal of Climate<\/em>, 28, 1494-1509. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00246.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Qian Cheng*, <strong>\u5468\u6587<\/strong>, Soi Kun Fong, and Ka Cheng Leong, 2015: Two Approaches for Statistical Prediction of Non-Gaussian Climate Extremes: A Case Study of Macao Hot Extremes during 1912\u20132012. <em>Journal of Climate<\/em>, 28, 623-636. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00159.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2014<\/h3><p>Xia Qu, Gang Huang*, and <strong>\u5468\u6587<\/strong>, 2014: Consistent responses of East Asian summer mean rainfall to global warming in CMIP5 simulations. <em>Theoretical and Applied Climatology<\/em>, 117, 123-131. <a href=\"https:\/\/doi.org\/10.1007\/s00704-013-0995-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, <strong>\u5468\u6587<\/strong>*, Chongyin Li, and Dongxiao Wang, 2014: Comparison of the impact of two types of El Ni\u00f1o on\u00a0tropical cyclone genesis over the South China Sea. <em>International Journal of Climatology<\/em>, 34, 2651-2660. <a href=\"https:\/\/doi.org\/10.1002\/joc.3865\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Dongxiao Wang*, Xin Wang, <strong>\u5468\u6587<\/strong>, and Chongyin Li, 2014: Comparisons of Two Types of El Ni\u00f1o Impacts on TC Genesis over the South China Sea. <em>Advances in Natural and Technological Hazards Research<\/em>, vol 40. <a href=\"https:\/\/doi.org\/10.1007\/978-3-642-40695-9_17\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, <strong>\u5468\u6587<\/strong>*, and Tim Li, 2014: Influences of the Pacific\u2013Japan Teleconnection Pattern on Synoptic-Scale Variability in the Western North Pacific. <em>Journal of Climate<\/em>, 27, 140-154. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-13-00183.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, <strong>\u5468\u6587<\/strong>*, Deliang Chen, Chongyin Li, and Jie Song, 2014: Water Vapor Transport and Moisture Budget over Eastern China: Remote Forcing from the Two Types of El Ni\u00f1o. <em>Journal of Climate<\/em>, 27, 8778-8792. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-14-00049.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2014: Interdecadal Change in South China Sea Tropical Cyclone Frequency in Association with Zonal Sea Surface Temperature Gradient. <em>Journal of Climate<\/em>, 27, 5468-5480. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-13-00744.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Wen Chen*, and <strong>\u5468\u6587<\/strong>, 2014: Assessment of future drought in Southwest China based on CMIP5 multimodel projections. <em>Advances in Atmospheric Sciences<\/em>, 31, 1035-1050. <a href=\"https:\/\/doi.org\/10.1007\/s00376-014-3223-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuyun Liu, Lin Wang*, <strong>\u5468\u6587<\/strong>, and Wen Chen, 2014: Three Eurasian teleconnection patterns: spatial structures, temporal variability, and associated winter climate anomalies. <em>Climate Dynamics<\/em>, 42, 2817-2839. <a href=\"https:\/\/doi.org\/10.1007\/s00382-014-2163-z\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong>*, and Deliang Chen, 2014: Summer High Temperature Extremes in Southeast China: Bonding with the El Ni\u00f1o\u2013Southern Oscillation and East Asian Summer Monsoon Coupled System. <em>Journal of Climate<\/em>, 27, 4122-4138. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/27\/11\/jcli-d-13-00545.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song*, Chongyin Li, and <strong>\u5468\u6587<\/strong>, 2014: High and low latitude types of the downstream influences of the North Atlantic Oscillation. <em>Climate Dynamics<\/em>, 42, 1097-1111. <a href=\"https:\/\/doi.org\/10.1007\/s00382-013-1844-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jian Ling*, Chongyin Li, <strong>\u5468\u6587<\/strong>, and Xiaolong Jia, 2014: To begin or not to begin? A case study on the MJO initiation problem. <em>Theoretical and Applied Climatology<\/em>, 115, 231-241. <a href=\"https:\/\/doi.org\/10.1007\/s00704-013-0889-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhenxi Zhang*, Mark Wenig, <strong>\u5468\u6587<\/strong>, Thomas Diehl, Ka-Lok Chan, and Lingna Wang, 2014: The contribution of different aerosol sources to the Aerosol Optical Depth in Hong Kong. <em>Atmospheric Environment<\/em>, 83, 145-154. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S1352231013008005\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2013<\/h3><p>Xiuzhen Li, <strong>\u5468\u6587<\/strong>*, Chongyin Li, and Jie Song, 2013: Comparison of the Annual Cycles of Moisture Supply over Southwest and Southeast China. <em>Journal of Climate<\/em>, 26, 10139-10158. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/26\/24\/jcli-d-13-00057.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xianjun Xiao*, Dongxiao Wang , <strong>\u5468\u6587<\/strong>, Zuqiang Zhang, Yinghao Qin, Na He, and Lili Zeng, 2013: Impacts of a wind stress and a buoyancy flux on the seasonal variation of mixing layer depth in the South China Sea. <em>Acta Oceanologica Sinica<\/em>, 32, 30-37. <a href=\"https:\/\/doi.org\/10.1007\/s13131-013-0349-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Weiwen Wang, <strong>\u5468\u6587<\/strong>*, Xin Wang, Soi Kun Fong, and Ka Cheng Leong, 2013: Summer high temperature extremes in Southeast China associated with the East Asian jet stream and circumglobal teleconnection. <em>Journal of Geophysical Research: Atmospheres<\/em>, 118, 8306-8319. <a href=\"https:\/\/doi.org\/10.1002\/jgrd.50633\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Qun Zhou, Wen Chen*, and <strong>\u5468\u6587<\/strong>, 2013: Solar cycle modulation of the ENSO impact on the winter climate of East Asia. <em>Journal of Geophysical Research: Atmospheres<\/em>, 118, 5111-5119. <a href=\"https:\/\/doi.org\/10.1002\/jgrd.50453\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2013: Modulation of Western North Pacific Tropical Cyclone Activity by the ISO. Part II: Tracks and Landfalls. <em>Journal of Climate<\/em>26, 2919-2930. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-12-00211.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2013: Modulation of Western North Pacific Tropical Cyclone Activity by the ISO. Part I: Genesis and Intensity. <em>Journal of Climate<\/em>, 26, 2904-2918. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-12-00210.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, <strong>Wen Zhou*<\/strong>, Hing Yim Mok, Man Chi Wu, and Yaping Shao, 2013: Revisiting the climatology of atmospheric blocking in the Northern Hemisphere. <em>Advances in Atmospheric Sciences<\/em>, 30, 397-410. <a href=\"https:\/\/doi.org\/10.1007\/s00376-012-2006-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jong-Suk Kim, <strong>\u5468\u6587<\/strong>*, Hoffman H. N. Cheung, and <a href=\"https:\/\/link.springer.com\/article\/10.1007\/s00376-012-2074-z#auth-Chak_Hang-Chow-Aff1-Aff2\">Chak Hang Chow<\/a>, 2013: Variability and risk analysis of Hong Kong air quality based on Monsoon and El Ni\u00f1o conditions. <em>Advances in Atmospheric Sciences<\/em>, 30, 280-290. <a href=\"https:\/\/doi.org\/10.1007\/s00376-012-2074-z\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, <strong>\u5468\u6587<\/strong>*, Dongxiao Wang , and Chunzai Wang, 2013: The impacts of the summer Asian Jet Stream biases on surface air temperature in mid-eastern China in IPCC AR4 models. <em>International Journal of Climatology<\/em>, 33, 265-276. <a href=\"https:\/\/doi.org\/10.1002\/joc.3419\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, <strong>\u5468\u6587<\/strong>*, Yaping Shao, Wen Chen, Hing Yim Mok, and Man Chi Wu, 2013: Observational climatology and characteristics of wintertime atmospheric blocking over Ural\u2013Siberia. <em>Climate Dynamics<\/em>, 41, 63-79. <a href=\"https:\/\/doi.org\/10.1007\/s00382-012-1587-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang*, Chunzai Wang, <strong>\u5468\u6587<\/strong>, Lin Liu, and Dongxiao Wang , 2013: Remote influence of North Atlantic SST on the equatorial westerly wind anomalies in the western Pacific for initiating an El Ni\u00f1o event: an Atmospheric General Circulation Model Study. <em>Atmospheric Science Letters<\/em>, 14, 107-111. <a href=\"https:\/\/doi.org\/10.1002\/asl2.425\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jian Ling*, Chongyin Li, <strong>\u5468\u6587<\/strong>, Xiaolong Jia, and Chidong Zhang, 2013: Effect of boundary layer latent heating on MJO simulations. <em>Advances in Atmospheric Sciences<\/em>, 30, 101-115. <a href=\"https:\/\/doi.org\/10.1007\/s00376-012-2031-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2012<\/h3><p>Xiuzhen Li, and <strong>\u5468\u6587<\/strong>*, 2012: Quasi-4-Yr Coupling between El Ni\u00f1o\u2013Southern Oscillation and Water Vapor Transport over East Asia\u2013WNP. <em>Journal of Climate<\/em>, 25, 5879-5891. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-11-00433.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, and <strong>\u5468\u6587<\/strong>*, 2012: Changes in Western Pacific Tropical Cyclones Associated with the El Ni\u00f1o\u2013Southern Oscillation Cycle. <em>Journal of Climate<\/em>25, 5864-5878. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-11-00430.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Richard C. Y. Li, <strong>\u5468\u6587<\/strong>*, Johnny C. L. Chan, and P. Huang, 2012: Asymmetric Modulation of Western North Pacific Cyclogenesis by the Madden\u2013Julian Oscillation under ENSO Conditions. <em>Journal of Climate<\/em>, 25, 5374-5385. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-11-00337.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>John Xun Yang, Alexis Kai Hon Lau*, Jimmy Chi Hung Fung, <strong>\u5468\u6587<\/strong>, Mark Wenig, 2012: An air pollution episode and its formation mechanism during the tropical cyclone Nuri\u2019s landfall in a coastal city of south China. <em>Atmospheric Environment<\/em>, 54, 746-753. <a href=\"https:\/\/doi.org\/10.1016\/j.atmosenv.2011.12.023\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hoffman H. N. Cheung, <strong>\u5468\u6587<\/strong>*, Hing Yim Mok, and Man Chi Wu, 2012: Relationship between Ural\u2013Siberian Blocking and the East Asian Winter Monsoon in Relation to the Arctic Oscillation and the El Ni\u00f1o\u2013Southern Oscillation. <em>Journal of Climate<\/em>, 25, 4242-4257. <a href=\"https:\/\/doi.org\/10.1175\/JCLI-D-11-00225.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Huopo Chen*, Jianqi Sun, Xiaoli Chen, and <strong>\u5468\u6587<\/strong>, 2012: CGCM projections of heavy rainfall events in China. <em>International Journal of Climatology<\/em>, 32, 441-450. <a href=\"https:\/\/doi.org\/10.1002\/joc.2278\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, <strong>\u5468\u6587<\/strong>*, Chongyin Li, and Dongxiao Wang , 2012: Effects of the East Asian summer monsoon on tropical cyclone genesis over the South China Sea on an interdecadal time scale. <em>Advances in Atmospheric Sciences<\/em>, 29, 249-262. <a href=\"https:\/\/doi.org\/10.1007\/s00376-011-1080-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jong-Suk Kim, <strong>\u5468\u6587<\/strong>*, Xin Wang, and Shaleen Jain, 2012: El Ni\u00f1o Modoki and the Summer Precipitation Variability over South Korea: A Diagnostic Study. <em>Journal of the Meteorological Society of Japan. Ser. II<\/em>, 90, 673-684. <a href=\"https:\/\/doi.org\/10.2151\/jmsj.2012-507\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, Zhiping Wen, <strong>\u5468\u6587<\/strong>*, and Dongxiao Wang , 2012: Atmospheric Water Vapor Transport Associated with Two Decadal Rainfall Shifts over East China. <em>Journal of the Meteorological Society of Japan. Ser. II<\/em>, 90, 587-602. <a href=\"https:\/\/doi.org\/10.2151\/jmsj.2012-501\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yi Deng, Ping Shi, <strong>\u5468\u6587<\/strong>, Yan Du, Qiang Xie, Wei Zhuang, and Dongxiao Wang*, 2012: A dipole wind curl pattern induced by Taiwan Island and its effect on upper stratification in the northeastern South China Sea. <em>Chinese Journal of Oceanology and Limnology<\/em>, 30, 944-952. <a href=\"https:\/\/doi.org\/10.1007\/s00343-012-1260-2\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jong-Suk Kim, Richard Cheuk-Yin Li, and <strong>\u5468\u6587<\/strong>*, 2012: Effects of the Pacific-Japan teleconnection pattern on tropical cyclone activity and extreme precipitation events over the Korean peninsula. <em>Journal of Geophysical Research: Atmospheres<\/em>, 117. <a href=\"https:\/\/doi.org\/10.1029\/2012JD017677\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ningbo Jiang*, Kevin Cheung, Kehui Luo, Paul J. Beggs, and <strong>\u5468\u6587<\/strong>, 2012: On two different objective procedures for classifying synoptic weather types over east Australia. <em>International Journal of Climatology<\/em>, 32, 1475-1494. <a href=\"https:\/\/doi.org\/10.1002\/joc.2373\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuan Fang, Wen Chen*, and <strong>\u5468\u6587<\/strong>, 2012: Analysis of the role played by circulation in the persistent precipitation over South China in June 2010. <em>Advances in Atmospheric Sciences<\/em>, 29, 769-781. <a href=\"https:\/\/doi.org\/10.1007\/s00376-012-2018-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Youfang Yan*, Yiquan Qi, and <strong>\u5468\u6587<\/strong>, 2012: Variability of tropical cyclone occurrence date in the South China Sea and its relationship with SST warming. <em>Dynamics of Atmospheres and Oceans<\/em>, 55-56, 45-59. <a href=\"https:\/\/doi.org\/10.1016\/j.dynatmoce.2012.05.001\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Qizhong Wu, Zifa Wang, Huansheng Chen, <strong>\u5468\u6587<\/strong>*, and Mark Wenig, 2012: An evaluation of air quality modeling over the Pearl River Delta during November 2006. <em>Meteorology and Atmospheric Physics<\/em>, 116, 113-132. <a href=\"https:\/\/doi.org\/10.1007\/s00703-011-0179-z\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>*, Wen Chen, and Dongxiao Wang, 2012: The implications of El Ni\u00f1o-Southern Oscillation signal for South China monsoon climate. <em>Aquatic Ecosystem Health &amp; Management<\/em>, 15, 14-19. <a href=\"https:\/\/doi.org\/10.1080\/14634988.2012.652050\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, Dongxiao Wang , <strong>\u5468\u6587<\/strong>*, and Chongyin Li, 2012: Interdecadal modulation of the influence of La Ni\u00f1a events on mei-yu rainfall over the Yangtze River valley. <em>Advances in Atmospheric Sciences<\/em> ,29, 157-168. <a href=\"https:\/\/doi.org\/10.1007\/s00376-011-1021-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2011<\/h3><p>Weiwen Wang, Dongxiao Wang*, <strong>\u5468\u6587<\/strong>, Qinyan Liu, Yongqiang Yu, and Chao Li, 2011: Impact of the South China Sea throughflow on the pacific low-latitude western boundary current: A numerical study for seasonal and interannual time scales. <em>Advances in Atmospheric Sciences<\/em>, 28, 1367-1376. <a href=\"https:\/\/doi.org\/10.1007\/s00376-011-0142-4\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song*, <strong>\u5468\u6587<\/strong>, Xin Wang, and Chongyin Li, 2011: Zonal Asymmetry of the Annular Mode and Its Downstream Subtropical Jet: An Idealized Model Study. <em>Journal of the Atmospheric Sciences<\/em>, 68, 1946-1973. <a href=\"https:\/\/doi.org\/10.1175\/2011JAS3656.1\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ren-Jun Zhou*, Peng-Bing Liu, <strong>\u5468\u6587<\/strong>, Hong-Ke Cai, and Yue-Juan Chen, 2011: The analysis of quasi-biennial oscillation characteristics of stratospheric aerosol. <em>Acta Geophysica Sinica<\/em>, 54, 1174-1181. <a href=\"https:\/\/doi.org\/10.3969\/j.issn.0001-5733.2011.05.005\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhongwei Yan, Jiangjiang Xia, Cheng Qian, and <strong>\u5468\u6587<\/strong>*, 2011: Changes in seasonal cycle and extremes in China during the period 1960\u20132008. <em>Advances in Atmospheric Sciences<\/em>, 28, 269-283. <a href=\"https:\/\/doi.org\/10.1007\/s00376-010-0006-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>JIangjiang Xia, Zhongwei Yan*, and <strong>\u5468\u6587<\/strong>, 2011: Changes in Seasonality in China under Enhanced Atmospheric CO2 Concentration. <em>Atmospheric and Oceanic Science Letters<\/em>, 4, 12-17. <a href=\"https:\/\/doi.org\/10.1080\/16742834.2011.11446900\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Juan Feng, Wen Chen*, C.-Y. Tam, and <strong>\u5468\u6587<\/strong>, 2011: Different impacts of El Ni\u00f1o and El Ni\u00f1o Modoki on China rainfall in the decaying phases. <em>International Journal of Climatology<\/em>, 31, 2091-2101. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/joc.2217\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, Chunzai Wang, <strong>\u5468\u6587<\/strong>, Dongxiao Wang*, and Jie Song, 2011: Teleconnected influence of North Atlantic sea surface temperature on the El Ni\u00f1o onset. <em>Climate Dynamics<\/em>, 37, 663-676. <a href=\"https:\/\/doi.org\/10.1007\/s00382-010-0833-z\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xiuzhen Li, Zhiping Wen, and <strong>\u5468\u6587<\/strong>*, 2011: Long-term Change in Summer Water Vapor Transport over South China in Recent Decades. <em>Journal of the Meteorological Society of Japan. Ser. II<\/em>, 89A, 271-282. <a href=\"https:\/\/doi.org\/10.2151\/jmsj.2011-A17\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song, Chongyin Li, Jing Pan, and <strong>\u5468\u6587<\/strong>*, 2011: Climatology of Anticyclonic and Cyclonic Rossby Wave Breaking on the Dynamical Tropopause in the Southern Hemisphere. <em>Journal of Climate<\/em>, 24, 1239-1251. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/24\/4\/2010jcli3157.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yali Zhu*, Huijun Wang, <strong>\u5468\u6587<\/strong>, and Jiehua Ma, 2011: Recent changes in the summer precipitation pattern in East China and the background circulation. <em>Climate Dynamics<\/em>, 36, 1463-1473. <a href=\"https:\/\/doi.org\/10.1007\/s00382-010-0852-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Ke Wei*, Wen Chen, and <strong>\u5468\u6587<\/strong>, 2011: Changes in the East Asian cold season since 2000. <em>Advances in Atmospheric Sciences<\/em>, 28, 69-79. <a href=\"https:\/\/doi.org\/10.1007\/s00376-010-9232-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><\/div>\n\t\t\t\t\t\t\t\t\t<div class=\"elementor-tab-title elementor-tab-mobile-title\" aria-selected=\"false\" data-tab=\"5\" role=\"tab\" tabindex=\"-1\" aria-controls=\"elementor-tab-content-1125\" aria-expanded=\"false\">Before 2010<\/div>\n\t\t\t\t\t<div id=\"elementor-tab-content-1125\" class=\"elementor-tab-content elementor-clearfix\" data-tab=\"5\" role=\"tabpanel\" aria-labelledby=\"elementor-tab-title-1125\" tabindex=\"0\" hidden=\"hidden\"><h3>2010<\/h3><p>Youfang Yan*, Yiquan Qi, and <strong>\u5468\u6587<\/strong>, 2010: Interannual heat content variability in the South China Sea and its response to ENSO. <em>Dynamics of Atmospheres and Oceans<\/em>, 50, 400-414. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0377026510000357\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jian Huang*, Xin Wang, <strong>\u5468\u6587<\/strong>, Huijun Huang, Dongxiao Wang, and Faxiu Zhou, 2010: The characteristics of sea fog with different airflow over the Huanghai Sea in boreal spring. <em>Acta Oceanologica Sinica<\/em>, 29, 3-12. <a href=\"https:\/\/doi.org\/10.1007\/s13131-010-0045-8\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jin-Nan Yuan*, <strong>\u5468\u6587<\/strong>, Hui-Jun Huang, and Fei Liao, 2010: Observational analysis of asymmetric distribution of convection associated with tropical cyclones \u201cchanchu\u201d and \u201cprapiroon\u201d making landfall along the south China coast. <em>Journal of Tropical Meteorology<\/em>, 16, 171-180. <a href=\"https:\/\/doi.org\/10.3969\/j.issn.1006-8775.2010.02.009\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Dong-Xiao Wang *, <strong>\u5468\u6587<\/strong>, Xiao-Li Yu, Qiang Xie, and Xin Wang, 2010: Marine Atmospheric Boundary Layers Associated with Summer Monsoon Onset over the South China Sea in 1998. <em>Atmospheric and Oceanic Science Letters<\/em>, 3, 263-270. <a href=\"https:\/\/doi.org\/10.1080\/16742834.2010.11446880\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Zhongda Lin*, Riyu Lu, and <strong>\u5468\u6587<\/strong>, 2010: Change in early-summer meridional teleconnection over the western North Pacific and East Asia around the late 1970s. <em>International Journal of Climatology<\/em>, 30, 2195-2204. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/joc.2038\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Qizhong Wu, Zifa Wang*, A. Gbaguidi, Xiao Tang, and <strong>\u5468\u6587<\/strong>, 2010: Numerical Study of The Effect of Traffic Restriction on Air Quality in Beijing. <em>SOLA<\/em>, 6A, 17-20. <a href=\"https:\/\/doi.org\/10.2151\/sola.6A-005\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lian-Tong Zhou*, Chi-Yung Tam, <strong>\u5468\u6587<\/strong>, and Johnny C. L. Chan, 2010: Influence of South China Sea SST and the ENSO on winter rainfall over South China. <em>Advances in Atmospheric Sciences<\/em>, 27, 832-844. <a href=\"https:\/\/doi.org\/10.1007\/s00376-009-9102-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Qinyan Liu*, Dongxiao Wang, <strong>\u5468\u6587<\/strong>, Qiang Xie, and Yan Zhang, 2010: Covariation of the Indonesian throughflow and South China Sea throughflow associated with the 1976\/77 regime shift. <em>Advances in Atmospheric Sciences<\/em>, 27, 87-94. <a href=\"https:\/\/doi.org\/10.1007\/s00376-009-8061-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Wen Chen*, <strong>\u5468\u6587<\/strong>, Johnny C. L. Chan, David Barriopedro, and Ronghui Huang, 2010: Effect of the climate shift around mid 1970s on the relationship between wintertime Ural blocking circulation and East Asian climate. <em>International Journal of Climatology<\/em>, 30, 153-158. <a href=\"https:\/\/doi.org\/10.1002\/joc.1876\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Dehai Luo*, <strong>\u5468\u6587<\/strong>, and Ke Wei, 2010: Dynamics of eddy-driven North Atlantic Oscillations in a localized shifting jet: zonal structure and downstream blocking. <em>Climate Dynamics<\/em>, 34, 73-100. <a href=\"https:\/\/doi.org\/10.1007\/s00382-009-0559-y\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2009<\/h3><p><strong>\u5468\u6587<\/strong>*, Johnny C. L. Chan, Wen Chen, Jian Ling, Joaquim G. Pinto, and Yaping Shao, 2009: Synoptic-Scale Controls of Persistent Low Temperature and Icy Weather over Southern China in January 2008. <em>Monthly Weather Review<\/em>, 137, 3978-3991. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/mwre\/137\/11\/2009mwr2952.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song, <strong>\u5468\u6587<\/strong>*, Chongyin Li, and Lixin Qi, 2009: Signature of the Antarctic oscillation in the northern hemisphere. <em>Meteorology and Atmospheric Physics<\/em>, 105, 55-67. <a href=\"https:\/\/doi.org\/10.1007\/s00703-009-0036-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Wei Gu*, Chongyin Li, Weijing Li, <strong>\u5468\u6587<\/strong>, and Johnny C. L. Chan, 2009: Interdecadal unstationary relationship between NAO and east China\u2019s summer precipitation patterns. <em>Geophysical Research Letters<\/em>, 36. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2009GL038843\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Wei Gu*, Chongyin Li, Xin Wang, <strong>\u5468\u6587<\/strong>, and Weijing Li, 2009: Linkage between mei-yu precipitation and North Atlantic SST on the decadal timescale. <em>Advances in Atmospheric Sciences<\/em>, 26, 101-108. <a href=\"https:\/\/doi.org\/10.1007\/s00376-009-0101-5\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang*, Dongxiao Wang, and <strong>\u5468\u6587<\/strong>, 2009: Decadal variability of twentieth-century El Ni\u00f1o and La Ni\u00f1a occurrence from observations and IPCC AR4 coupled models. <em>Geophysical Research Letters<\/em>, 36. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/abs\/10.1029\/2009GL037929\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song*, Chongyin Li, <strong>\u5468\u6587<\/strong>, and Jing Pan, 2009: The linkage between the Pacific-North American teleconnection pattern and the North Atlantic Oscillation. <em>Advances in Atmospheric Sciences<\/em>, 26, 229-239. <a href=\"https:\/\/doi.org\/10.1007\/s00376-009-0229-3\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Lin Wang, Wen Chen*, <strong>\u5468\u6587<\/strong>, and Ronghui Huang, 2009: Interannual Variations of East Asian Trough Axis at 500 hPa and its Association with the East Asian Winter Monsoon Pathway. <em>Journal of Climate<\/em>, 22, 600-614. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/clim\/22\/3\/2008jcli2295.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>H.W. Tong, Johnny C. L. Chan*, and <strong>\u5468\u6587<\/strong>, 2009: The role of MJO and mid-latitude fronts in the South China Sea summer monsoon onset. <em>Climate Dynamics<\/em>, 33, 827-841. <a href=\"https:\/\/doi.org\/10.1007\/s00382-008-0490-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Hong-Ming Yan*, Chong-Yin Li, and <strong>\u5468\u6587<\/strong>, 2009: Influence of subtropical dipole pattern in Southern Indian Ocean on ENSO event. <em>Acta Geophysica Sinica<\/em>, 52, 2436-2449. <a href=\"https:\/\/doi.org\/10.3969\/j.issn.0001-5733.2009.10.003\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Chongyin Li, Xiaolong Jia, Jian Ling, <strong>\u5468\u6587<\/strong>, and Chidong Zhang*, 2009: Sensitivity of MJO simulations to diabatic heating profiles. <em>Climate Dynamics<\/em>, 32, 167-187. <a href=\"https:\/\/doi.org\/10.1007\/s00382-008-0455-x\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2008<\/h3><p>Yuan Yuan*, Johnny C. L. Chan, <strong>\u5468\u6587<\/strong>, and Chongyin Li, 2008: Decadal and interannual variability of the Indian Ocean Dipole. <em>Advances in Atmospheric Sciences<\/em>, 25, 856-866. <a href=\"https:\/\/doi.org\/10.1007\/s00376-008-0856-0\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuan Yuan*, Hui Yang, <strong>\u5468\u6587<\/strong>, and Chongyin Li, 2008: Influences of the Indian Ocean dipole on the Asian summer monsoon in the following year. <em>International Journal of Climatology<\/em>, 28, 1849-1859. <a href=\"https:\/\/doi.org\/10.1002\/joc.1678\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuan Yuan*, <strong>\u5468\u6587<\/strong>, Hui Yang, and Chongyin Li, 2008: Warming in the northwestern Indian Ocean associated with the El Ni\u00f1o event. <em>Advances in Atmospheric Sciences<\/em>, 25, 246-252. <a href=\"https:\/\/doi.org\/10.1007\/s00376-008-0246-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Yuan Yuan, <strong>\u5468\u6587<\/strong>, Johnny C. L. Chan*, and Chongyin Li, 2008: Impacts of the basin-wide Indian Ocean SSTA on the South China Sea summer monsoon onset. <em>International Journal of Climatology<\/em>, 28, 1579-1587. <a href=\"https:\/\/doi.org\/10.1002\/joc.1671\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xuhua Cheng, Yiquan Qi*, and <strong>\u5468\u6587<\/strong>, 2008: Trends of sea level variations in the Indo-Pacific warm pool. <em>Global and Planetary Change<\/em>, 63, 57-66. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0921818108000647\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Martin L. M. Wong, Johnny C. L. Chan*, and <strong>\u5468\u6587<\/strong>, 2008: A Simple Empirical Model for Estimating the Intensity Change of Tropical Cyclones after Landfall along the South China Coast. <em>Journal of Applied Meteorology and Climatology<\/em>, 47, 326-338. <a href=\"https:\/\/journals.ametsoc.org\/view\/journals\/apme\/47\/1\/2007jamc1633.1.xml\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2007<\/h3><p><strong>\u5468\u6587<\/strong>*, Xin Wang, Tianjun Zhou, Chongyin Li, and Johnny C. L. Chan, 2007: Interdecadal variability of the relationship between the East Asian winter monsoon and ENSO. <em>Meteorology and Atmospheric Physics<\/em>, 98, 283-293. <a href=\"https:\/\/doi.org\/10.1007\/s00703-007-0263-6\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang, Chongyin Li, and <strong>\u5468\u6587<\/strong>*, 2007: Interdecadal mode and its propagating characteristics of SSTA in the South Pacific. <em>Meteorology and Atmospheric Physics<\/em>, 98, 115-124. <a href=\"https:\/\/doi.org\/10.1007\/s00703-006-0235-2\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Dehai Luo*, Tingting Gong, Yina Diao, and <strong>\u5468\u6587<\/strong>, 2007: Storm tracks and annular modes. <em>Geophysical Research Letters<\/em>, 34. <a href=\"https:\/\/doi.org\/10.1029\/2007GL030436\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>, and Johnny C. L. Chan*, 2007: ENSO and the South China Sea summer monsoon onset. <em>International Journal of Climatology<\/em>, 27, 157-167. <a href=\"https:\/\/doi.org\/10.1002\/joc.1380\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>, Chongyin Li, and Xin Wang*, 2007: Possible connection between Pacific Oceanic interdecadal pathway and east Asian winter monsoon. <em>Geophysical Research Letters<\/em>, 34. <a href=\"https:\/\/doi.org\/10.1029\/2006GL027809\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2006<\/h3><p>Chongyin Li*, <strong>\u5468\u6587<\/strong>, Xiaolong Jia, and Xin Wang, 2006: Decadal\/interdecadal variations of the ocean temperature and its impacts on climate. <em>Advances in Atmospheric Sciences<\/em>, 23, 964-981. <a href=\"https:\/\/doi.org\/10.1007\/s00376-006-0964-7\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Jie Song*, <strong>\u5468\u6587<\/strong>, Jing Pan, and Chongyin Li, 2006: Global influence of the Northern Hemisphere second mode of the zonal average of the zonal wind. <em>Geophysical Research Letters<\/em>, 33. <a href=\"https:\/\/doi.org\/10.1029\/2006GL026380\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>*, Chongyin Li, and Johnny C. L. Chan, 2006: The interdecadal variations of the summer monsoon rainfall over South China. <em>Meteorology and Atmospheric Physics<\/em>, 93, 165-175. <a href=\"https:\/\/doi.org\/10.1007\/s00703-006-0184-9\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Xin Wang*, Chongyin Li, and <strong>\u5468\u6587<\/strong>, 2006: Interdecadal variation of the relationship between Indian rainfall and SSTA modes in the Indian Ocean. <em>International Journal of Climatology<\/em>, 26, 595-606. <a href=\"https:\/\/doi.org\/10.1002\/joc.1283\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><h3>2005<\/h3><p><strong>\u5468\u6587<\/strong>, and Johnny C. L. Chan*, 2005: Intraseasonal oscillations and the South China Sea summer monsoon onset. <em>International Journal of Climatology<\/em>, 25, 1585-1609. <a href=\"https:\/\/rmets.onlinelibrary.wiley.com\/doi\/abs\/10.1002\/joc.1209\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p>Johnny C. L. Chan*, and <strong>\u5468\u6587<\/strong>, 2005: PDO, ENSO and the early summer monsoon rainfall over south China. <em>Geophysical Research Letters<\/em>, 32. <a href=\"https:\/\/doi.org\/10.1029\/2004GL022015\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><p><strong>\u5468\u6587<\/strong>*, Johnny Chung-Leung Chan, and Chongyin Li, 2005: South China Sea summer monsoon onset in relation to the off-equatorial ITCZ. <em>Advances in Atmospheric Sciences<\/em>, 22, 665-676. <a href=\"https:\/\/doi.org\/10.1007\/BF02918710\">[\u8bba\u6587\u4e3b\u9875]<\/a><\/p><\/div>\n\t\t\t\t\t\t\t<\/div>\n\t\t<\/div>\n\t\t\t\t<\/div>\n\t\t\t\t<\/div>\n\t\t\t\t\t<\/div>\n\t\t\t\t<\/div>\n\t\t<div class=\"elementor-element elementor-element-752a680 e-flex e-con-boxed e-con e-parent\" data-id=\"752a680\" data-element_type=\"container\" data-core-v316-plus=\"true\">\n\t\t\t\t\t<div class=\"e-con-inner\">\n\t\t\t\t\t<\/div>\n\t\t\t\t<\/div>\n\t\t<div class=\"elementor-element elementor-element-ff18218 e-flex e-con-boxed e-con e-parent\" data-id=\"ff18218\" data-element_type=\"container\" data-core-v316-plus=\"true\">\n\t\t\t\t\t<div class=\"e-con-inner\">\n\t\t\t\t<div class=\"elementor-element elementor-element-9e43350 elementor-widget-divider--view-line elementor-widget elementor-widget-divider\" data-id=\"9e43350\" data-element_type=\"widget\" data-widget_type=\"divider.default\">\n\t\t\t\t<div class=\"elementor-widget-container\">\n\t\t\t<style>\/*! 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L. Chan, 2025: Shifting hotspot of tropical cyclone clusters in a warming climate, Nature Climate Change, 15, accepted. [PDF] Widana A. E. Lakshani, Wen [&hellip;]<\/p>","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-131","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"http:\/\/www.wenzhou-clim.com\/zh\/wp-json\/wp\/v2\/pages\/131","targetHints":{"allow":["GET"]}}],"collection":[{"href":"http:\/\/www.wenzhou-clim.com\/zh\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"http:\/\/www.wenzhou-clim.com\/zh\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"http:\/\/www.wenzhou-clim.com\/zh\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"http:\/\/www.wenzhou-clim.com\/zh\/wp-json\/wp\/v2\/comments?post=131"}],"version-history":[{"count":199,"href":"http:\/\/www.wenzhou-clim.com\/zh\/wp-json\/wp\/v2\/pages\/131\/revisions"}],"predecessor-version":[{"id":1507,"href":"http:\/\/www.wenzhou-clim.com\/zh\/wp-json\/wp\/v2\/pages\/131\/revisions\/1507"}],"wp:attachment":[{"href":"http:\/\/www.wenzhou-clim.com\/zh\/wp-json\/wp\/v2\/media?parent=131"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}