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李清泉(Qingquan Li)

  李清泉

   研究员(二级)

liqq@cma.gov.cn

010-58995693



研究兴趣

气候异常机理和气候变化,气候模式模拟与预测,季风和海气相互作用


教育背景

199309—199607,北京大学,地球物理系,理学博士

199009—199307,南京气象学院,气象系,理学硕士

198609—199007,南京气象学院,气象系,理学学士


研究经历

200411-至今, 中国气象局,国家气候中心,研究员

200210-200306,美国国家海洋大气管理局,气候预报中心,访问学者

199806-199808,澳大利亚气象局,研究中心,访问学者

199907-200410,中国气象局,国家气候中心,副研究员

199607-199906,中国气象局,国家气候中心,助理研究员


承担课题

1. 国家重点研发计划课题(202312-202811,课题负责人)

2. 国家自然科学基金气象联合基金项目(202301-202612,项目负责人)

3. 国家重点研发计划国际创新科技合作项目(202301-202512,项目负责人)

4. 安徽省自然科学基金气象联合基金项目(202301-202512,项目负责人)

5. 中国气象局创新发展专项(202301-202412,项目负责人)

6. 国家“第二次青藏高原综合科学考察研究”项目(201911-202410,子专题负责人)

7. 中国科学院战略性先导科技专项A类项目“西风-季风作用与亚洲水塔变化及其广域影响和绿色发展方案” (201803-202302,子课题负责人)

8. 国家自然基金重大计划课题“北极海--气系统与冬季欧亚大陆极端事件的联系”, (201801-202212,专题负责人)

9. 国家自然科学基金面上项目“北半球环状模及其指数异常事件形成的动力学机理和诊断方法研究”(201201-201512,骨干参加)

10. 国家自然科学基金重点项目“ARGO资料同化与海气耦合过程研究”(200301-200612,骨干参加)

11. 国家自然科学基金青年项目“三维全球海洋碳循环环流模式的建立及数值模拟研究” (200201-200412,项目负责人)

12. 国家重点基础研究发展计划(973)课题“东亚季风区年际-年代际气候变率机理与预测研究”(201201-201608,课题负责人)

13. 国家重点基础研究发展计划(973)课题“气候变暖背景下亚洲季风与我国南方旱 涝灾害的关系” 课题(201301-201712,专题负责人)

14. 国家科技支撑项目“灾害性天气精细数值预报系统及短期气候集合预测研究”(200601-200912,专题负责人)

15. 中国气象局气象行业标准项目“西南雨季监测指标研制”(201401-201512,项目负责人)


教学经历

20186月,海-气相互作用与海洋资料同化,研究生,扬州大学物理学院

20066月,ENSO机理与监测预测,研究生,南京信息工程大学大气科学学院


学术兼职

1. 中国气象局气候预测研究重点开放实验室主任 202306-至今

2. 中国青藏高原研究会理事 202001-至今

3. 安徽省气象学会学术委员会委员 202201-至今

4. 中国气象局第三极区域气候中心(北京)筹备专家组专家 202112 —至今

5. 寿县国家气候观象台(中国气象局淮河流域典型农田生态气象野外科学试验基地)学术委员会委员 202405-至今

6. 联合国政府间气候变化专门委员会(IPCC) “二氧化碳捕获和存贮” 特别报告的主要作者、以及第四次评估报告的评审专家 200301-201012


获奖情况

1. 2023年云南省自然科学二等奖

2. 2022年甘肃省科技进步一等奖

3. 2020年中国气象局科技创新气象领军人才、首席科学家

4. 2013年全国“三八红旗手”

5. 2012年国家科技进步二等奖

6. 2012年海洋工程科学技术一等奖

7. 2007年联合国政府间气候变化专门委员会“诺贝尔和平奖”贡献奖

8. 2005年中国气象局气象科技成果应用二等奖

9. 2004年中国气象局科技进步一等奖

10. 2004年北京气象学会优秀气象科技论文三等奖

11. 1999年新疆维吾尔自治区自然科学优秀论文一等奖


发表论文 (5年发表论文, * 表示通讯作者)

1. Li Qingquan, Miao Bi, Song Yang, Qingyuan Wu, Yihui Ding, Xinyong Shen, Xiaoting Sun, Mengchu Zhao.2024.Winter extreme precipitation over the Tibetan Plateau influenced by Arctic sea ice on interdecadal timescale. Advances in Climate Change Research, https://doi.org/10.1016/j.accre.2024.01.006

2. Wu Qingyuan, Qingquan Li*, Xiaoming Hu, Xiaoting Sun. 2024. Process-based attribution of summer upper-tropospheric temperature related to South Asian summer monsoon. J Climate. 371683-1701DOI: 10.1175/JCLI-D-23-0329.1

3. Yu Jingwen, Qingquan LI*, Yihui Ding, Zhiping Wen, Zhiqiang Gong, Xiaoting Sun, Xinyong Shen, Lili Dong. 2024. AMO modulation of interdecadal background of persistent heavy rainfall in summer over the Huaihe River Basin. Climate Dynamics. https://doi.org/10.1007/s00382-023-07088-9

4. Sun Xiaoting, Qingquan Li*, Qingyuan Wu. 2024. Mechanisms of early and late summer precipitation in Southwest China: Dynamic and thermodynamic processes. Climate Dynamics.

5. Lu Geman, Qingquan Li*, Xiaoting Sun, et al. 2024. Comparative analysis of peak-summer heatwaves in the Yangtze–Huaihe River Basin of China in 2022 and 2013: Thermal effects of the Tibetan Plateau. Atmospheric Research. 300 (2024) 107222https://doi.org/10.1016/j.atmosres.2024.107222

6. Li Chang, Liang Zhao, Qingquan Li*, Xinyong Shen, et al.2024.The changing characteristics of torrential rainfall in the Huaihe River Basin from 1961 to 2020. Environmental Research Communications.

7. Wang ZunyaQingquan Li. 2024.Validation of GSMaP data in depicting precipitation climatology and climate variability in China. Remote Sensing, 16, 755

8. Guo Li, Jie WU, Qingquan Li, et al. 2024 Advantages of multi-model ensemble on sub-seasonal precipitation prediction in China and the driving role of MJO. Adv. Atmos. Sci

9. Zhang Han, Xin-Zhong Liang, Yongjiu Dai, Lianchun Song, Qingquan Li, Fang Wang, Shulei Zhang . 2024. CWRF downscaling with improved land surface initialization enhances spring-summer seasonal climate prediction skills in China. Journal of Climate. https://doi.org/10.1175/JCLI-D-23-0565.1

10. Tuo Ya, Panjie Qiao, Feng Zhang, Wenqi Liu, Qingquan Li2024Predicting summer precipitation anomalies in the Yunnan-Guizhou plateau using spring sea-surface temperature anomalies. Atmosphere. 15(4), 453; https://doi.org/10.3390/atmos15040453

11. Wang Weiwei, Tuantuan Zhang, Junwen Chen, Qingquan Li, Song Yang, Yi Deng, 2024. Quantitative attribution of the temperature associated with winter extreme cold events in China. Climate Dynamics, 62:413–429, https://doi.org/10.1007/s00382-023-06906-4

12. Wu Chunyu, Qingquan Li*, Lili Dong, Hongming Yan, Dongqian Wang, Xiaoting Sun. 2023. Rainy season onset date in Southwest China and the related atmospheric circulations. Atmospheric Research. 298 (2024) 107127,  https://doi.org/10.1016/j.atmosres.2023.107127

13. Li XiyiQingquan Li*Yihui Ding, Song Yang, et al. 2023. Possible influence of the interdecadal variation of the extratropical southern Indian Ocean SST on East Asian summer monsoon precipitation. Atmospheric Research. 288 (2023) 106721. https://doi.org/10.1016/j.atmosres.2023.106721

14. Zhao Chongbo, Qingquan Li*, Yu Nie,Fang Wang, Bing Xie, Lili Dong, Jie Wu. 2023. The reversal of surface air temperature anomalies in China between early and late winter 2021/2022: Observations and predictions, Advances in Climate Change Research. https://doi.org/10.1016/j.accre.2023.09.004

15. Zhang Shiyu, Minghao Wang, Lanning Wang, Xin-Zhong Liang, Chao Sun, Qingquan Li*. 2023. Sensitivity of the simulation of extreme precipitation events in China to different cumulus parameterization schemes and the underlying mechanisms. Atmospheric Research 285 (2023) 106636. https://doi.org/10.1016/j.atmosres.2023.106636

16. Yu Liwei, Si DongDabang Jiang, Yihui Ding, Xinyong Shen, Xianmei Liang, Qingquan Li, Zhiping Tian. 2023. Tibetan Plateau booster effect on the influence of Atlantic multidecadal variability on the East Asian summer rainfall. Journal of Climate, 36, 3437-3452.  DOI: 10.1175/JCLI-D-22-0472.1.

17. Yu Liwei, Dong Si, Xinyong Shen, Xianmei Lang, Ran Zhang, Qingquan Li. 2023. Impact of Tibetan Plateau vertical heating on the Asian summer monsoon on the interdecadal scale. Atmospheric Science Letters, e1140. https://doi.org/10.1002/asl.1140

18. Zhao Liang , Wei Dong, Xinyong Shen, Yihui Ding, Qingquan Li, Yamin Hu, Ziniu Xiao, et al. 2023. Human activity and simultaneous high pressure anomalies influence the long- duration cold events of winter in China. Climate Dynamics , https://doi.org/10.1007/s00382-023-06719-5

19. Zhao Liang, Yunwen LiuYihui DingQingquan LiWei DongXinyong ShenWei ChengHaoxin YaoZiniu Xiao.2023. The Warm Arctic–Cold Eurasia pattern and its key region in winter in CMIP6 model simulations. Advances in Atmospheric Sciences. 10.1007/s00376-022-2201-4

20. Peng TingtingLiang ZhaoLing ZhangXinyong ShenYihui DingJingsong WangQingquan LiYanju LiuYamin HuJian LingZhihui LiCunrui Huang. 2023. Changes in temperature-precipitation compound extreme events in China during the past119 years. Earth and Space Science, 10, e2022EA002777. https://doi.org/10.1029/2022EA002777

21. Ding Yihui, Sun XiaotingQingquan Li. 2023. Interdecadal variation in Rossby wave source over the Tibetan Plateau and its impact on the East Asia circulation pattern during boreal summer. Atmosphere, 14, 541. https://doi.org/10.3390/ .

22. Wang Weiwei, Song Yang, Qingquan Li, Xingwen Jiang, 2023. Alternate modulations of ENSO and the Arctic Oscillation on winter extreme cold events in China. Atmospheric Research.https://doi.org/10.1016/j.atmosres.2022.106532

23. Wang Weiei, Song Yang, Tuantuan Zhang, Qingquan Li, and Wei Wei, 2022: Sub-seasonal prediction of the South China Sea summer monsoon onset in the NCEP Climate Forecast System Version 2. Adv. Atmos. Sci., doi.org/10.1007/s00376-022-1403-0.

24. Li Xiucang, Ping Wu, Yihui Ding, Yanju Liu, Qingquan Li. 2022. Spatial-temporal variation of precipitation recycling over the Tibetan Plateau under climate warming. Atmospheric Research, doi.org/10.1016/j.atmosres.2022.106431

25. Wu  Jie, Ying Liu, Yongsheng Li, Jinqing Zuo, Yu Nie, Qingquan Li, Shuai Zhang, Dongqian Wang.  2022. The extreme Northeast China cold vortex activities in the late spring of 2021 and possible causes involved. Advances in Climate Change Research, doi.org/10.1016/j.accre.2022.09.002.

26. Sun Xiaoting, Qinghua Ding, Simon Wang, Dániel Topál, Qingquan Li, Christopher CastroHaiyan TengRui Luo, Yihui Ding . 2022. Enhanced jet stream waviness induced by suppressed tropical Pacific convection during boreal summer. Nature Communications. Nature Communications. 13, 1288 (2022) https://doi.org/10.1038/s41467-022-28911-7

27. Yao Haoxin, Liang Zhao, Xinyong Shen, Ziniu Xiao, Qingquan Li. 2022. Relationship between summer compound hot and dry extremes in China and the snow cover pattern in the preceding winter. Front. Earth Sci. 10:834284.

28. Yang Yumeng, Liang Zhao, Xinyong Shen, Ziniu Xiao, Qingquan Li. 2022. The spring heat source over the Qinghai–Tibetan Plateau linked with the winter warm Arctic–cold Siberia pattern impacting summer drought in China. Front. Earth Sci. 10:835101.

29. Liu Yunwen, Liang Zhao, Guirong Tan, Xinyong Shen, Suping Nie, Qingquan Li, Li Zhang. 2021. Evaluation of multidimensional simulations of summer air temperature in China from CMIP5 to CMIP6 by the BCC Models: from trends to modes. Advances in Climate Change Research, https://doi.org/10.1016/ j.accre.2021.12.001.

30. Yu JingwenQingquan Li*, Yihui Dinget al. 2022. The long-term trend of water vvapor over the Tibetan Plateau in boreal summer under global warming. China Science: Earth Science. 65, 662; doi: 10.1007/s11430-021-9874-0

31. Wu Qingyuan, Qingquan Li*,Yihui Ding, et al.2022. Asian summer monsoon responses to the change of land-sea thermodynamic contrast in a warming climate: CMIP6 projections. Advances in Climate Change Research.  Advances in Climate Change Research, 13 (2022) 205e217.

32. Zhang Yingxian, Dong Si, Yihui Ding, Dabang Jiang, Qingquan Li, Guofu Wang. 2022: Influence of major stratospheric sudden warming on the unprecedented cold wave in East Asia in January 2021. Adv. Atmos. Sci., doi: 10.1007/s00376-022-1318-9.

33. Bi, Miao, Li, Qingquan*, Song Yang, et al. 2021.Effects of Arctic Sea Ice in Autumn on extreme cold events over the Tibetan Plateau in the following winter: Possible Mechanisms. Climate Dynamics. doi.org/10.1007/s00382-021-06007-0

34. Li Qingquan*, Mengchu Zhao, Song Yang, Xinyong Shen, Lili Dong, Zhaodong Liu. 2021. A zonally oriented teleconnection pattern induced by heating of the western Tibetan Plateau in boreal summer. Climate Dynamics. 57:2823–2842

35. Yan Li, Qingyuan Wang, Qingquan Li, Yiwei Liu, Yan Wang. 2021. An asymmetric variation of hot and cold SST extremes in the China Seas during the recent warming hiatus period. Scientific reports.11-2014.

36. Sun XiaotingDing YihuiLi Qingquan. 2021 Interdecadal variation of the atmospheric heat source over the Tibetan Plateau and surrounding Asian Monsoon region: Impact on the Northern Hemisphere summer circulation. J. Meteor. Res. 35(2), 1-20.

37. Li Qingquan, Wang Tao, Wang Fang, Xin-Zhong Liang, Chongbo Zhao, Lili Dong,  Chunyu Zhao, Bing Xie. 2021. Dynamical downscaling simulation of the East Asian summer monsoon in a regional Climate-Weather Research and Forecasting model. Int J Climatol. 41. DOI: 10.1002/joc.6800

38. Li Qingquan, Juanhuai Wang, Song Yang, Fang Wang, Jie Wu, Yamin Hu. 2020: Sub-seasonal prediction of rainfall over the South China Sea and its surrounding areas during spring-summer transitional season. Int J Climatol. 40: 4326–4346.

39. Wang Qing-yuan, Yan Li, Qing-quan Li *, Yan Wang. 2020. Sea surface temperature extremes of different intensity in the China seas during the global warming acceleration and hiatus periods. Journal of Tropical Meteorology. 26(4):473-481.

40. Dániel Topál1, Qinghua Ding, Jonathan Mitchell, Ian Baxter, Mátyás Herein, Tímea Haszpra, Rui Luo, Qingquan Li. 2020. An internal atmospheric process determining summertime Arctic sea ice melting in the next three decades: Lessons learned from five large ensembles and multiple CMIP5 climate simulations. Journal of Climate. 33: 7431-7454.

41. 董李丽,张焓,李清泉*,汪方,赵崇博,谢冰. 2024. 不同分辨率CWRF模式对中国区域气温模拟的比较研究. 气候变化研究进展, 20 (2): 129-145.

42. 姚昊昕,李清泉*,赵亮,吴星麒,沈新勇,段春锋,李畅. 2024. 淮河流域暖季极端高温干旱复合事件的演变特征及其与气候和植被的关系.生态学报. 44(13):1-13.

43. 张宇,李清泉,朱锦华,沈新勇,毕淼,吴清源. 2024. 5月南极涛动对青藏高原西部夏季气温影响的诊断分析,气象.50(3)344-356.

44. 赵嘉诚, 李清泉,丁一汇,刘芸芸 ,谭桂容,沈新勇,吴清源. 2023. 21世纪第210年初华北夏季降水年代际增加及与大气环流异常的联系,气象学报. 81(5): 764-775.

45. 张焓,梁信忠,汪方,谢冰,李清. 2023. CWRF降尺度提高BCC_CSM1.1m对中国夏季降水跨季度动力预测能力,大气科学学报,2161-179.

46. 朱万林,李清泉*,王遵娅,沈新勇. 2022. 60年中国冷空气过程气候变率分析,气象,48(1)1-13

47. 俞静雯,李清泉*,丁一汇,张杰, 吴清源, 沈新勇. 2021.气候变暖背景下青藏高原夏季水汽的长期变化趋势分析. 中国科学:地球科学.

48. 王娟怀, 李清泉*, 汪方, 杨守懋,胡娅敏. 2021.基于DERF2.0的华南前汛期降水订正预测.应用气象学报, 32(1):115-128.

49. 王璠,李清泉*,孙银川,王岱, 郑广芬, 朱晓炜. 2021. 宁夏冬季极端低温事件特征及其与秋季北极海冰异常的联系.高原气象,404):887-897.

50. 王庆元,李清泉,李琰,刘一玮王亚男. 2021.1982–2019 年渤、黄海海洋热浪时空变化特征分析. 海洋学报, 43(12)38–49

51. 赵萌初, 李清泉, 沈新勇, 王庆元. 2021. 1984-2017ISCCP-FH辐射资料在青藏高原地区的适用性评估.气象,47(1)11-23.

52. 汤秭晨,李清泉,王黎娟,伍丽泉. 2021. CanESM5MIROC6模式CMIP6年代际试验中国气温预测能力评估.气候变化研究进展, 17 (2): 162-174.

53. 王冰笛,李清泉,沈新勇,董李丽汪方王涛梁信忠. 2020. 区域气候模式CWRF 对东亚冬季风气候特征的模拟. 地球科学进展, 353):319-330.


出版书籍

1.李清泉,封国林, 等,2019. 全球变化背景下东亚地区气候年际-年代际变率及其可预报性研究. 北京, 科学出版.

2.  李清泉,王东阡, 等,  2016. 东亚季风年鉴2015. 北京,气象出版社.

3.  李维京,陈丽娟,李清泉,等. 2012. 现代气候业务. 北京,气象出版社


其它情况

李清泉个人主页:http://ncclcs.ncc-cma.net/Website/?NewsID=3621



  #以上信息由本人提供,更新时间:2024/10/14