姓名：张梦琪

邮箱：zhangmengqi@mail.iap.ac.cn

研究方向：气候变化、短期气候预测、海-气相互作用

教育经历：

2013—2019   中国科学院大气物理研究所，获理学博士学位

2009—2013   中山大学，获理学学士学位

工作经历：

2019.6—2022.9  中国科学院大气物理研究所，博士后

2022.9—至今      中国科学院大气物理研究所，副研究员

2025.11—至今    竺可桢—南森国际研究中心，副主任

Eduation:

2013—2019  Ph.D,  Institute of Atmospheric Physics, Chinese Academy of Sciences, China

Work Experience:

2019.6—2022.9     Postdoc, Institute of Atmospheric Physics, Chinese Academy of Sciences

2025.11—current  Deputy Director of Nansen-Zhu International Research Centre

第一/通讯作者论文：

1.    Zhang MQ, Sun JQ. 2025: Extreme spring droughts in Yunnan Province under different ENSO phases in 2023 and 2024: possible mechanisms and dynamical predictions. Climate Dynamics, 63, 309. https://doi.org/10.1007/s00382-025-07786-6. 

2.   Zhang MQ, Sun JQ. 2024: Bias of ENSO-like SST breaks the connection between the North Atlantic SST and Northeast China spring precipitation in the NCEP CFSv2. Climate Dynamics, 62, 6505–6518. 

3.    Zhang MQ, Sun JQ. 2023: Increased persistence in winter to spring precipitation anomalies over South China since the late 1990s and the possible mechanisms. Journal of Climate, 36, 7179-7198. 

4.    Sun YK, Wang YF, Zhang MQ*, Zeng ZX. 2023: Summer extreme consecutive dry days over Northeast China in the changing climate: Observed features and projected future changes based on CESM-LE. Frontiers in Earth Science, 11, 1138985. 

5.    Zhang MQ, Sun JQ, Gao YQ. 2022: Impacts of North Atlantic sea surface temperature on the predominant modes of spring precipitation monthly evolution over Northeast China. Climate Dynamics, 58, 1383–1401.

6.    张梦琪, 孙建奇, 郜永祺. 2022: 前冬戴维斯海峡-巴芬湾区域海冰异常对中国东部春季极端降水频次的可能影响及预测价值. 地学前缘, 29, 401–409.

7.    Zhang MQ, Sun JQ. 2021. Impact of October snow cover in central Siberia on the following spring extreme precipitation frequency in southern China. Frontiers in Earth Science, 9: 785601.

8.    Zhang MQ, Sun JQ. 2020: Increased role of late winter sea surface temperature variability over northern tropical Atlantic in spring precipitation prediction over Northeast China. Journal of Geophysical Research: Atmospheres, 125, e2020JD033232. 

9.    Sun JQ, Zhang MQ, 2019: Decadal change in the sea level pressure prediction skill over the Mediterranean region and its contribution to downstream surface air temperature prediction. Climate Dynamics, 53, 5187–5202. 

10.  Zhang MQ, Sun JQ, 2019: Increased predictability of spring precipitation over central East China around the late 1970s. Journal of Climate, 32, 3599–3614. 

11.  Zhang MQ, Sun JQ, 2018: Enhancement of the spring East China precipitation response to tropical sea surface temperature variability. Climate Dynamics, 51, 3009–3021.  

合作论文：

1.    Liu YX, Sun JQ, Zhang MQ, He SP. 2026. Synergistic prediction value of preceding winter ENSO and Bering Sea ice for spring warm front activity over the eastern Yangtze River basin. Atmospheric Research, https://doi.org/10.1016/j.atmosres.2025.108676.

2.    Han SZ, Ren HL, Sun JQ, Zhang MQ. 2025. Connection of autumn north Asian snow with mid‐winter Tibetan Plateau snow. Geophysical Research Letters, https://doi.org/10.1029/2025GL118606.

3.    Liu YX, Sun JQ, Zhang MQ. 2025. Influence and prediction value of winter U.S. east coast trough for spring cold front frequency over the Middle and Lower Reaches of the Yangtze River. Journal of Geophysical Research: Atmospheres, https://doi.org/10.1029/2025JD043601.

4.    He XM, Sun JQ, Yu S, Zhang MQ. 2025. Regime shift in extreme wildfires within northern Eurasia and their impacts. Environmental Research Letters, 20, https://doi.org/10.1088/1748-9326/ae0b92.

5.    Ju DY, Sun JQ, Hong HX, Zhang MQ. 2024. Atmospheric teleconnections responsible for the dominant patterns of interannual variability in summer drought over northern Asia. Journal of Climate, 37, 4183–4203

6.    Yu S, Zhang MQ, Li XX. 2022. Phase-shift mode of the East Asian trough from December to February: Characteristic and possible mechanisms. Frontiers in Earth Science. 10, 1014011.

7.    Nan YT, Sun JQ, Zhang MQ, Hong HX, Nie YB, Yuan JP, 2022: Enhancement of the relationship between spring extreme precipitation over Southwest China and preceding winter sea surface temperature anomalies over the South Indian Ocean after the late 1980s. International Journal of Climatology, 42, 8539-8551.

8.    Nan YT, Sun JQ, Zhang MQ, Hong HX, Yuan JP, 2022: Strengthened influence of the East Asian trough on spring extreme precipitation variability over eastern Southwest China after the late 1980s. Atmospheric and Oceanic Science Letters, 15, 1674–2834.

9.    李晨曦, 曾子旋, 洪海旭, 张梦琪, 孙建奇, 华维, 2022: 东北春季极端连续无雨日与前冬北太平洋海平面气压的可能联系.气象科学. 42, 143–151.

10.   Gu LT, Sun JQ, Yu S, Zhang MQ. 2021. Footprints of Pacific Decadal Oscillation in the interdecadal variation of consecutive cloudy–rainy events in southern China. Atmospheric Research, 257: 105609. 

11.   Li XX, Sun JQ, Zhang MQ, Zhang Y, Ma JH. 2021. ‏Possible connection between declining Barents Sea ice and interdecadal increasing northeast China precipitation in May. International Journal of Climatology, 41: 6270–6282. 

12.   Zhang Y, Zhang MQ, Ma JH, Wang T. 2021. Possible contribution of Arctic sea ice decline to intense warming over Siberia in June. Atmospheric and Oceanic Science Letters, 15, https://doi.org/10.1016/j.aosl.2021.100132.

13.   艾雅雯, 孙建奇, 韩双泽, 张梦琪, 华维, 2020: 1961−2016年中国春季极端低温事件的时空特征分析.大气科学, 44, 1305−1319.

14.   何博翰, 孙建奇, 于恩涛, 王会军, 张梦琪, 华维, 2020: 大兴安岭和长白山地形影响东北夏季降水的数值模拟研究.气候与环境研究, 25, 268−280.

15.   Sun JQ, Ming J, Zhang MQ, Yu S. 2018 Circulation features associated with the record-breaking rainfall over South China in June 2017. Journal of Climate, 31: 7209–7224. 

国家自然科学基金委青年科学基金项目（负责人，2022-2024）

国家重点研发计划（骨干，2024-2029）