个人简介

中国气象科学研究院灾害天气国家重点实验室，研究员，长期从事季风动力学和次季节至季节预测理论和方法研究，现任中国气象科学研究院次季节至季节变化研究创新团队骨干成员。

先后主持、参与科技部国家重点研发专项课题、国家自然科学基金青年、面上、重点项目等国家级科研项目10余项；发表学术论文70余篇（其中SCI论文50余篇），第一/通讯作者论文近40篇；被SCI和CSCD引用1700余次，3篇论文入选ESI全球高被引论文数据库。

曾获多项省部级科技奖励和荣誉称号，担任多个气象学和地学类权威学术期刊审稿人。

主要学术贡献

1. 揭示了冬夏季节转换进程中热带对流发展对季风高空环流的影响机理和瞬变过程；
2. 建立了从高、低空环流垂直耦合认识亚洲夏季风爆发次季节过程及其可预报性的理论框架；
3. 阐明了洋盆海温联动和热带-中纬度环流耦合的多样性特征及其气候效应；

4. 揭示了近年来我国持续性极端气候事件的成因及其动力预测不确定性的共性来源。

主要研究方向

1. 季风气候动力学

2. 海-陆-气相互作用

3. 次季节至季节变化机理及其预测

4. 极端天气气候事件

招收大气、海洋及相关专业知识背景的硕士、博士研究生。

个人学术网页：https://www.researchgate.net/profile/Boqi-Liu （ResearchGate）

https://scholar.google.com.hk/citations?user=IXakNJwAAAAJ&hl=zh-CN（Google Scholar）‪

教育经历

• 2009年09月-2013年05月：南京信息工程大学大气科学学院，气象学，理学博士；
• 2006年09月-2009年06月：南京信息工程大学大气科学学院，气象学，理学硕士；
• 2002年09月-2006年06月：南京信息工程大学大气科学学院、大气科学，理学学士。

工作经历

• 2021年12月-至今：中国气象科学研究院灾害天气国家重点实验室，研究员。
• 2015年12月-2021年11月：中国气象科学研究院气候系统研究所，副研究员；
• 2015年05月-2015年11月：中国气象科学研究院气候系统研究所，助理研究员；
• 2013年05月-2015年04月：中国科学院大气物理研究所LASG国家重点实验室，博士后。

主持/参与科研项目情况

主持

1. 2024年1月-2027年12月：国家自然科学基金面上项目，“亚洲夏季风爆发联合模态和洋盆海温联动对我国东部汛期降水季节进程的协同影响”，50万元，在研；

2. 2018年12月-2021年12月：科技部国家重点研发专项课题，“东亚30-90天气候变异与我国持续性异常事件成因”，217万，已结题；

3. 2018年01月-2021年12月：国家自然科学基金面上项目，“热带海温与青藏高原热力强迫协同变化对亚洲夏季风爆发的影响研究”，68万，已结题；
4. 2018年05月-2020年12月：气科院基本科研业务费重点项目，“次季节至季节气候预测理论和方法研究”，234万，已结题；
5. 2016年01月-2018年12月：国家自然科学基金青年项目，“4-5月南亚高压形态变化对ENSO的响应及其对南亚夏季风爆发的调控”，21万，已结题；
6. 2014年01月-2015年5月：中国博士后科学基金面上资助（一等），“印度洋暖池区跨赤道海温异常对印度夏季风爆发的影响”，8万，已结题。

参与

1. 2019年01月-2023年12月：国家自然科学基金重点项目，“东亚夏季风次季节模态变化的关键物理过程、变化机理和可预报性研究”，280万，在研。
2. 2017年01月-2019年12月：国家自然科学基金重大研究计划集成项目，“青藏高原地-气耦合过程和海洋对区域能量和水分循环及全球气候的协同影响”，335万，已结题；
3. 2014年01月-2017年12月：国家自然科学基金重大研究计划重点项目，“青藏高原与热带海洋对东亚季风年际变率的协同影响”，300万，已结题；
4. 2013年09月-2018年12月：中国科学院战略性先导科技专项(A类)，“东印暖池对年际气候变化信号的影响和响应”，657万，已结题；
5. 2013年01月-2016年12月：国家自然科学基金面上项目，“夏季亚洲大地形双加热的变异及其对亚洲季风的影响”，148万，已结题；
6. 2011年01月-2013年12月：国家自然科学基金面上项目，“东亚副热带夏季风建立时间、特征及其可能机制研究”，55万，已结题。

2024

[1]      He Manshu, Liu Boqi*, 2024: Different mechanisms of air temperature anomalies in the Yangtze River between early and late summer. Atmospheric Research, 300, 107249, doi: 10.1016/j.atmosres.2024.107249.

2023

[2]      Liu Boqi*, Zhu Congwen, Ma Shuangmei, Yan Yuhan, Jiang Ning, 2023: Subseasonal processes of triple extreme heatwaves over the Yangtze River Valley in 2022. Weather and Climate Extremes. doi: 10.1016/j.wace.2023.100572.

[3]      段亚楠, 刘伯奇*, 2023: 不同再分析资料中的南海夏季风爆发气候特征和年际变率. 大气科学. doi:10.3878/j.issn.1006-9895.2210.22079.

[4]      Liu Boqi*, Zhu Congwen, Xu Kang, Ma Shuangmei, Lu Mengmeng, Han Xue, Hua Lijuan, 2023: Record-breaking Pre-flood Rainfall over South China in 2022: Role of Historic Warming over the Northeast Pacific and Maritime Continent. Climate Dynamics. doi:10.1007/s00382-023-06734-6.

[5]      Gao Lu, Han Xue, Chen Xingrong, Liu Boqi, Li Yan, 2023: The Spring Drought in Yunnan Province of China: Variation Characteristics, Leading Impact Factors and Physical Mechanisms. Atmosphere, 14, doi:10.3390/atmos14020294.

[6]      Liu Boqi*, Duan Yanan, 2023: Diverse Interannual Variability of Asian Summer Monsoon Onset Process. Geophysical Research Letters, 50, doi:10.1029/2022gl100583.

[7]      Yan Yuhan, Zhu Congwen, Liu Boqi, 2023: Subseasonal predictability of the July 2021 extreme rainfall event over Henan China in S2S operational models. Journal of Geophysical Research: Atmospheres, 128, e2022JD037879. doi: 10.1029/2022JD037879.

[8]      Jiang Ning, Liu Boqi, Zhu Congwen, Chen Yanying, 2023: Remote linkage of record-breaking U.S. tornado outbreaks to the tropical cyclone in western North Pacific in December 2021. Environmental Research Letters, doi: 10.1088/1748-9326/acc880.

[9]      Han Tongxin, Xu Kang, Wang Lijuan, Liu Boqi, Tam C-Y, Liu Kai, Wang Weiqiang, 2023: Extremely long-lived marine heatwave in South China Sea during summer 2020: Combined effects of the seasonal and intraseasonal variations. Global and Planetary Change, 230, 104261, doi: 10.1016/j.gloplacha.2023.104261.

[10]   Wu Weichen, Wang Yaqiang, Wei Fengying, Liu Boqi, You Xiaoxiong, 2023: Extended-Range Forecast of Regional Persistent Extreme Cold Events Based on Deep Learning. Atmosphere, 14, doi: 10.3390/atmos14101572.

[11]   Wang Meirong, Yao Xiuping, Wang Jun, Liu Boqi, Zhu Zhu, Zhou Shunwu, Yuan Jiashuang 2023: Spatial Heterogeneity of Summer Rainfall Trends over the Tibetan Plateau Contributed by Different Rainfall Intensities, Remote Sensing, 15, doi:10.3390/rs15235587.

2022

[12]   Liu Boqi*, Zhu Congwen, Ma Shuangmei, Yan Yuhan, 2022: Combined effects of tropical Indo-Pacific-Atlantic SST anomalies on record-breaking floods over Central-North China in September 2021. Journal of Climate, 35, 6191-6205. doi:10.1175/JCLI-D-21-0988.1.

[13]   Liu Kai, Xu Kang, Zhu Congwen, Liu Boqi, 2022: Diversity of Marine Heatwaves in the South China Sea regulated by the ENSO phase. Journal of Climate, 35, 877-893. doi:10.1175/JCLI-D-21-0309.1.

[14]   Yan Yuhan, Liu Boqi, Zhu Congwen, Lu Riyu, Jiang Ning, Ma Shuangmei, 2022: Subseasonal forecast barrier of the North Atlantic oscillation in S2S models during the extreme mei-yu rainfall event in 2020. Climate Dynamics, 58. 2913-2925. doi:10.1007/s00382-021-06076-1

[15]   Zhu Congwen, Liu Boqi, Li Lun, Ma Shuangmei, Jiang Ning, Yan Yuhan, 2022: Progress and prospects of research on subseasonal to seasonal variability and prediction of the East Asian monsoon. Journal of Meteorological Research, 36, 677-690. doi:10.1007/s13351-022-2059-5.

2021

[16]   Liu Boqi*, Zhu Congwen, Jiang Ning, Guo Li, 2021: Seasonal Evolution of Anomalous Rainband over East China Regulated by Sea Surface Temperature Anomalies in the Northern Hemisphere. Journal of Climate, 34, 3087-3102. DOI:10.1175/JCLI-D-20-0398.1.

[17]   Liu Boqi*, Zhu Congwen, 2021: Subseasonal-to-Seasonal Predictability of Onset Dates of South China Sea Summer Monsoon: A Perspective of Meridional Temperature Gradient. Journal of Climate, 34, 5601-5616. DOI: 10.1175/jcli-d-20-0696.1.

[18]   Yan Yuhan, Liu Boqi*, Zhu Congwen, 2021: Subseasonal Predictability of South China Sea Summer Monsoon Onset with the ECMWF S2S Forecasting System. Geophysical Research Letters, 48, e2021GL095943, doi:10.1029/2021GL095943.

[19]   Zhu Congwen, Liu Boqi, Xu Kang, Jiang Ning, Liu Kai, 2021: Diversity of the Coupling Wheels in the East Asian Summer Monsoon on interannual timescale: Challenge of Summer Rainfall Forecast in China.       Advances in Atmospheric Sciences, 38, 546-554. DOI: 10.1007/s00376-020-0199-z.

[20]   Li Jianying, Liu Boqi, Mao Jiangyu, 2021: Climatological intraseasonal oscillation in the middle–upper troposphere and its effect on the northward migration of the East Asian westerly jet and rain belt over eastern China. International Journal of Climatology, 41, 5084-5099. DOI: 10.1002/joc.7118.

[21]   Yan Yuhan, Zhu Congwen, Liu Boqi, Jiang Song, 2021: Annual Cycle of East Asian Precipitation Simulated by CMIP6 Models. Atmosphere, 12, DOI: 10.3390/atmos12010024.

[22]   Guo Li, Zhu Congwen, Liu Boqi, 2021: Regulation of the subseasonal variability of winter rainfall in South China by the diversity of El Niño Southern Oscillation. Climate Dynamics, 56, 1919-1936. DOI:10.1007/s00382-020-05565-z.

[23]   Li Lun, Zhu Congwen, Zhang Renhe, Liu Boqi, 2021: Roles of the Tibetan Plateau vortices in the record Meiyu rainfall in 2020. Atmospheric Science Letters, 22, e1017, DOI: 10.1002/asl.1017.

[24]   Liu Bo, Su Jingzhi, Ma Libin, Tang Yanli, Rong Xinyao, Li Jian, Chen Haoming, Liu Boqi, Hua Lijuan, Wu Renguang, 2021: Seasonal prediction skills in the CAMS-CSM climate forecast system. Climate Dynamics, DOI: 10.1007/s00382-021-05848-z.

[25]   Shen Hongyan, Gong Zhiqiang, Liu Boqi, Guo Yipeng, Feng Xiaoli, Wen Tingting, Wang Xiaojuan, Feng Guolin, 2021: Remote Effects of IOD and ENSO on Motivating the Atmospheric Pattern Favorable for Snowfall Over the Tibetan Plateau in Early Winter. Frontiers in Climate, 3, doi:10.3389/fclim.2021.694384.

[26]   马双梅, 祝从文, 刘伯奇, 2021: 2019年4~6月云南持续性高温天气的大气环流异常成因. 大气科学, 45, 401-415.

[27]   张正秋, 祝从文, 苏京志, 刘伯奇, 蒋宁, 陈昊明, 2021: 气候动力诊断和分析系统设计与应用. 应用气象学报, 32, 542-552.

[28]   刘伯奇, 段亚楠, 李健颖, 毛江玉, 2021: 春季青藏高原大气热源季节内振荡特征及其维持机制. 高原气象, 40, 1419-1431.

2020

[29]   Liu Boqi*, Zhu Congwen, 2020: Boosting effect of tropical cyclone “Fani” on the onset of the South China Sea summer monsoon in 2019. Journal of Geophysical Research: Atmospheres, 125, DOI:10.1029/2019JD031891.

[30]   Liu Boqi*, Zhu Congwen, 2020: Diverse impacts of the Siberian high on surface air temperature in Northeast China during boreal winter   . International Journal of Climatology, 40, 594-603. DOI: 10.1002/joc.6199.

[31]   Liu Boqi, Yan Yuhan, Zhu Congwen, Ma Shuangmei, Li Jianying, 2020: Record-Breaking Meiyu Rainfall Around the Yangtze River in 2020 Regulated by the Subseasonal Phase Transition of the North Atlantic Oscillation. Geophysical Research Letters, 47, DOI: 10.1029/2020GL090342.

[32]   刘伯奇*, 祝从文, 2020: 中国夏季降水预测因子潜在技巧分布图及应用. 应用气象学报, 31, 570-582.

[33]   Jin Qihua, Liu Boqi*, He Jinhai, 2019: Possible causes for the asymmetric evolution between the aerosol optical depth over East Asia and eastern United States during boreal spring. International Journal of Climatology, 39, 2474-2483. DOI: 10.1002/joc.5936.

[34]   Xu Kang, Liu Boqi, Liu Yu, Wang Weiqiang, He Zhuoqi, 2020: Effects of monsoon onset vortex on heat budget in the mixed layer of the Bay of Bengal. Journal of Oceanology and Limnology, 38, 1616-1631.

[35]   Xu Kang, Tam C-Y, Liu Boqi, Chen Sheng, Yang Xiaoyi, He Zhuoqi, Xie Qiang, Wang Weiqiang, 2020: Attenuation of Central Pacific El Niño Amplitude by North Pacific Sea Surface Temperature Anomalies. Journal of Climate, 33, 6673–6688. DOI: 10.1175/jcli-d-19-0767.1.

[36]   Xu Kang, Miao H-Y, Liu Boqi, Tam C-Y, Wang Weiqiang, 2020:     Aggravation of record-breaking drought over the mid-to-lower reaches of the Yangtze River in the post-monsoon season of 2019 by anomalous Indo-Pacific oceanic conditions. Geophysical Research Letters, 47, DOI: 10.1029/2020GL090847.

2019

[37]   Liu Boqi*, Zhu Congwen, 2019: Extremely Late Onset of the 2018 South China Sea Summer Monsoon Following a La Niña Event: Effects of Triple SST Anomaly Mode in the North Atlantic and a Weaker Mongolian Cyclone. Geophysical Research Letters, 46, 2956-2963. DOI: 10.1029/2018GL081718.

[38]   Liu Boqi*, Congwen Zhu, 2019: Weak linkage of winter surface air temperature over Northeast Asia with East Asian winter monsoon during 1993–2003. Climate Dynamics, 53, 6107-6124. DOI: 10.1007/s00382-019-04915-w.

[39]   Liu Boqi, Congwen Zhu, Su Jingzhi, Ma Shuangmei, Xu Kang, 2019: Record-Breaking Northward Shift of the Western North Pacific Subtropical High in July 2018. Journal of the Meteorological Society of Japan, 97, 913-925. DOI: 10.2151/jmsj.2019-047.

[40]   郭莉, 刘伯奇*, 祝从文, 2019: 2018/2019年冬季江南超长连阴雨天气特征及其成因. 科学通报, 64, 3498-3509.

[41]   Hao Yuqian, Liu Boqi, Zhu Congwen, He Bian, 2019: Asymmetry in the dominant co-variation mode of boreal summer monsoon rainfall regulated by the ENSO evolution. Climate Dynamics, 53, 6379-6396. DOI: 10.1007/s00382-019-04933-8.

[42]   Xu Kang, Wang Weiqiang, Liu Boqi, Zhu Congwen, 2019: Weakening of the El Niño amplitude since the late 1990s and its link to decadal change in the North Pacific climate. International Journal of Climatology, 39, 4125-4138. DOI: 10.1002/joc.6063.

[43]   Guo Li, Zhu Congwen, Liu Boqi, 2019: Possible causes of the flooding over south China during the 2015/2016 winter.    International Journal of Climatology, 39, 3218-3230. DOI: 10.1002/joc.6013.

[44]   Orsolini Yvan, Wegmann Martin, Dutra Emanuel, Liu Boqi, Balsamo Gianpaolo, Yang Kun, de Rosnay Patricia, Zhu Congwen, Wang Wenli, Senan Retish, Arduini Gabriele, 2019: Evaluation of snow depth and snow cover over the Tibetan Plateau in global reanalyses using in situ and satellite remote sensing observations. The Cryosphere, 13, 2221-2239. DOI: 10.5194/tc-13-2221-2019.

[45]   祝从文, 刘伯奇, 左志燕, 袁乃明, 刘舸, 2019: 东亚夏季风次季节变化研究进展. 应用气象学报, 30, 401-415.

2018

[46]   Liu Boqi, Zhu Congwen, Su Jingzhi, Hua Lijuan, Duan Yihong, 2018: Why was the western Pacific subtropical anticyclone weaker in late summer after the 2015/2016 super El Niño? International Journal of Climatology, 38, 55-65. DOI: 10.1002/joc.5160.

[47]   Hao Yuqian, Liu Boqi*, Zhu Congwen, Ma Shuangmei, 2018: The Interannual Dominant Co-variation Mode of Boreal Summer Monsoon Rainfall during 1979–2014. Journal of Climate, 31, 4193-4213. DOI: 10.1175/jcli-d-17-0423.1.

[48]   Guo Li, Zhu Congwen, Liu Boqi, Ma Shuangmei, 2018: Subseasonal variation of winter rainfall anomalies over South China during the mature phase of super El Niño events. Atmospheric and Oceanic Science Letters, 11, 396-403.

[49]   Ma Shuangmei, Zhu Congwen, Liu Boqi, Zhou Tianjun, Ding Yihui, Orsolini Yvan, 2018: Polarized Response of East Asian Winter Temperature Extremes in the Era of Arctic Warming.  Journal of Climate, 31, 5543-5557. DOI: 10.1175/jcli-d-17-0463.1.

2017

[50]   Liu Boqi*, hu Congwen Zhu, Yuan Yuan, 2017: Two interannual dominant modes of the South Asian High in May and their linkage to the tropical SST anomalies. Climate Dynamics, 49, 2705-2720.

[51]   黄青兰, 刘伯奇*, 李菲, 2017: 由冬至夏北半球副热带地区大气热源的季节转换特征及其可能机制. 大气科学, 41, 1010-1026.

[52]   Xu Kang, Tam C-Y, Zhu Congwen, Liu Boqi, Wang Weiqiang, 2017: CMIP5 Projections of Two Types of El Niño and Their Related Tropical Precipitation in the Twenty-First Century. Journal of Climate, 30, 849-864. DOI: 10.1175/jcli-d-16-0413.1.

2016

[53]   Liu Boqi*, hu Congwen, 2016: A possible precursor of the South China Sea summer monsoon onset: Effect of the South Asian High. Geophysical Research Letters, 43, DOI:10.1002/2016gl071083.

[54]   He Jinhai, Liu Boqi*, 2016: The East Asian Subtropical Summer Monsoon: Recent Progress. Journal of Meteorological Research, 30, 135-155. DOI: 10.1007/s13351-016-5222-z.

[55]   Liu Boqi*, hu Congwen, Yuan Yuan, Xu Kang, 2016: Two Types of Interannual Variability of South China Sea Summer Monsoon Onset Related to the SST Anomalies before and after 1993/94.       Journal of Climate, 29, 6957-6971. DOI: 10.1175/JCLI-D-16-0065.1.

[56]   Song Zehao, Zhu Congwen, Su Jingzhi, Liu Boqi, 2016: Coupling Modes of Climatological Intraseasonal Oscillation in the East Asian Summer Monsoon. Journal of Climate, 29, 6363-6382. DOI: 10.1175/JCLI-D-15-0794.1.

[57]   Hao Yuqian, Zhu Congwen, Liu Boqi, 2016: Discrepancies in boreal summer monsoon rainfall between GPCP and CMAP products during 1979–2014. Atmospheric and Oceanic Science Letters, 9, 226-233.

[58]   刘屹岷, 刘伯奇, 任荣彩, 段安民, 毛江玉, 2016: 当前重大厄尔尼诺事件对我国春夏气候的影响. 中国科学院院刊, 31, 241-250.

[59]   李永生, 刘伯奇*, 王莹, 李菲, 2016: 非绝热加热对6月东北冷涡形成演变的影响及其可能机制. 气象与环境学报, 32, 19-26.

[60]   吴国雄, 何编, 刘屹岷, 包庆, 任荣彩, 刘伯奇, 2016: 青藏高原和亚洲夏季风动力学研究的新进展. 大气科学, 40, 22-32.

2015

[61]   Liu Boqi, Liu Yimin, Wu Guoxiong, Yan Jinghui, He Jinhai, Ren Suling, 2015: Asian summer monsoon onset barrier and its formation mechanism. Climate Dynamics, 45, 711-726. DOI: 10.1007/s00382-014-2296-0.

[62]   Liu Boqi, Wu Guoxiong, Ren Rongcai, 2015: Influences of ENSO on the vertical coupling of atmospheric circulation during the onset of South Asian summer monsoon. Climate Dynamics, 45, 1859-1875. DOI: 10.1007/s00382-014-2439-3.

[63]   Li Jianying, Liu Boqi, Li Jiandong, Mao Jiangyu, 2015: A comparative study on the dominant factors responsible for the weaker-than-expected El Niño event in 2014. Advances in Atmospheric Sciences, 32, 1381-1390. DOI: 10.1007/s00376-015-4269-6.

[64]   刘伯奇, 李健颖, 毛江玉, 任荣彩, 刘屹岷, 2015: 2014年赤道东太平洋ElNiño事件发展以及停滞过程的成因. 科学通报, 60, 2136-2148.

[65]   刘伯奇, 何金海, 2015: 亚洲夏季风动力学研究综述. 热带气象学报, 31, 869-880.

[66]   张盈盈, 李忠贤, 刘伯奇*, 2015: 春季青藏高原表面感热加热的年际变化特征及其对印度夏季风爆发时间的影响. 大气科学, 39, 1059-1072.

[67]   刘超, 刘屹岷, 刘伯奇, 2015: 6种地表热通量资料在伊朗—青藏高原地区的对比分析. 气象科学, 35, 398-404.

[68]   Wu Guoxiong, Duan Anmin, Liu Yimin, Mao Jiangyu, Ren Rongcai, Bao Qing, He Bian, Liu Boqi, Hu Wenting, 2015: Tibetan Plateau climate dynamics: recent research progress and outlook. National Science Review, 2, 100-116. DOI: 10.1093/nsr/nwu045.

2014及之前

[69]   何金海, 刘伯奇*, 吴国雄, 2014:      春末夏初南亚高压的形成过程及其与ENSO事件的联系. 大气科学, 38, 670-684.

[70]   吴国雄, 林海, 邹晓蕾, 刘伯奇, 何编, 2014: 全球气候变化研究与科学数据       地球科学进展, 29, 15-22.

[71]   Wu Guoxiong, Liu Boqi*, 2014: Role of forced and inertially unstable convection development in the onset process of Indian summer monsoon. Science China Earth Sciences, 57, 1438-1451. DOI: 10.1007/s11430-014-4865-9.

[72]   吴国雄, 段安民, 刘屹岷, 颜京辉, 刘伯奇, 任素玲, 张亚妮, 王同美, 梁潇云, 关月, 2013: 关于亚洲夏季风爆发的动力学研究的若干近期进展. 大气科学, 37, 211-228.

[73]   秦育婧, 王黎娟, 何金海, 管兆勇, 卢楚翰, 刘伯奇, 2013: 4~5月南亚高压重建过程与中南半岛对流活动的关系. 热带气象学报, 29, 115-121.

[74]   王黎娟, 郭帅宏, 何金海, 管兆勇, 刘伯奇, 2013: 4~5月南亚高压建立早晚年份环流差异及其可能成因. 大气科学, 37, 1165-1178.

[75]   Wu Guoxiong, Ren Suling, Xu Jianmin, Wang Dongxiao, Bao Qing, Liu Boqi, Liu Yimin, 2013: Impact of tropical cyclone development on the instability of South Asian High and the summer monsoon onset over Bay of Bengal. Climate Dynamics, 41, 2603-2616.

[76]   Liu Boqi, Wu Guoxiong, Mao Jiangyu, He Jinhai, 2013: Genesis of the South Asian High and Its Impact on the Asian Summer Monsoon Onset.     Journal of Climate, 26, 2976-2991. DOI: 10.1175/JCLI-D-12-00286.1.

[77]   Liu Boqi, He Jinhai, Wang Lijuan, 2012: On a possible mechanism for southern Asian convection influencing the South Asian high establishment during winter to summer transition. Journal of Tropical Meteorology, 18, 473-484.

[78]   刘伯奇, 何金海, 王黎娟, 2009: 4~5月南亚高压在中南半岛上空建立过程特征及其可能机制. 大气科学, 33, 1319-1332.

获奖情况

1. 2023年，中国气象科学研究院“优秀研究生导师”（司局级）；

2. 2022年，中国气象局“十三五”优秀气象科技成果（省部级，排名第二）；

4. 2019年，日本气象学会优秀论文奖（省部级，排名第一）；

5. 2018年，中国气象局“重大气象服务先进个人”称号（省部级）；

6. 2014年，江苏省教育厅“江苏省优秀博士学位论文”（省部级）；
7. 2010年，江苏省教育厅“江苏省优秀硕士学位论文”（省部级）。

学术兼职

1. 2014年至今，担任《大气科学》、《中国科学: 地球科学》、《气象学报》、《Nature Commnunication》、《Journal of Climate》、《Climate Dynamics》、《Journal of Geophysical Research-Atmospheres》、《International Journal of Climatology》、《Atmospheric Research》、《Atmospheric Science Letters》、《Dynamics of Atmospheres and Oceans》、《Advances in Atmospheric Sciences》、《Journal of Meteorological Research》、《Environment Research Letters》、《Atmosphere》等10余种国内、外大气科学类学术期刊审稿人。
2. 2021年12月至2024年12月，中国科学院南海海洋研究所，担任专业学位兼职导师。
3. 2021年12月至2022年3月，冬奥北京气象中心，担任第24届北京冬奥会预报预测专家组成员。
4. 2023年1月起，《高原气象》，青年编委（第一届）。