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1. Zhu , W ., & Shi , J .* (202 5 ). Interdecadal modulation of AMO on the relationship between spring Arctic Oscillation and the following winter ENSO . Climate Dynamics, 63, 137.
2 . Tang , Y ., & Shi , J .* (202 5 ). Impacts of cold SST anomalies in the subpolar N orth Atlantic on summer temperature anomalies in Eurasia . Journal of Climate , in press .
3 . S hi, J.* , Lu , Y ., Chen , J ., & Li , Z . (202 5 ). Teleconnections and drivers of Northeast P acific blob - like cooling in November . Climate Dynamics , https://doi.org/10.1007/s00382 - 025 - 07665 - 0 .
4 . Zhang , Y ., Shi , J .* , Chen , Y ., & Huang , F. (202 5 ). Intraseasonal relationship of winter temperatures in North America and warm sea surface temperatures in the Northeast Pacific. Atmospheric Research, 313, 107773.
5 . S hi, J.* , Huang, H., Fedorov, A., Holbrook, N., Zhang, Y., Ding, R., Luo, Y., Wang, S., Chen, J., Hu, X., Liu, Q., Huang, F., & Lin, X. (2024). Northeast Pacific warm blobs sustained via extratropical atmospheric teleconnections. Nature Communications. 15, 2832.
6 . Chen, J., Li, R., Mao, J., Yu, W., Xie, S., Wei, J., Huang, H., Liu, Q., & Shi, J . * (2024). Different modulations of Arctic Oscillation on wintertime sea surface temperature anomalies in the Northeast Pacific. Journal of Geophysical Research: Atmospheres, 129, e2024JD041360.
7 . Shi, J. * , Wang, J., Ren, Z. , Tang, C., & Huang, F.* (2023). Cold blobs in the subpolar North Atlantic: seasonality, spatial pattern, and driving mechanisms. Ocean Dynamics , 73, 267 – 278.
8 . Hu, X., Shi, J.* , Ma, X., Ding, R., Jing, Z., & Zhang, Y. (2023). Distinct features of mid - winter North Pacific storm track suppression associated with central and eastern Pacific El Niños . Atmospheric Research , 289, 106769 .
9 . C hen, J., Li, R., Xie, S., Wei, J., & Shi, J . * (2023). Characteristics and mechanisms of long - lasting 2021 – 2022 summer Northeast Pacific warm blobs . Frontiers in Marine Science , 10, 1158932 .
10 . Tang, C., Shi, J.* , Zhang, Y., Wang, S., Li, C., Lu, R., Yu, T., Wang, R., & Chen, Z. (202 3) . Changes and m echanisms of l ong - l ived w arm b lobs in the Northeast Pacific in l ow - w arming c limates . Journal of Climate, 36(7), 2277 – 2292.
11 . Shi, J.* , Tang, C., Liu, Q., Zhang, Y., Yang, H., & Li, C.* (2022). Role of mixed layer depth in the location and development of the Northeast Pacific warm blobs. Geophysical Research Letters, 49, e2022GL098849.
12 . Shi, J.* , Wu, K., Qian, W., Huang, F., Li, C., & Tang, C. (2021). Characteristics, trend, and precursors of extreme cold events in northwestern North America. Atmospheric Research, 249, 105338.
1 3 . Chen, Z., Shi, J.* , Liu, Q., Chen, H., & Li, C. (2021). A persistent and intense marine heatwave in the Northeast Pacific during 2019 – 2020. Geophysical Research Letters, 48, e2021GL093239.
1 4 . Tang, C., Shi, J.* , & Li, C. (2021). Long - lived cold blobs in the Northeast Pacific linked with the tropical La Niña. Climate Dynamics, 57, 223 – 237.
1 5 . Chen, H., Shi, J.* , Jin, Y., Geng, T., Li, C., & Zhang, X. (2021). Warm and cold episodes in western Pacific warm pool and their linkage with ENSO asymmetry and diversity. Journal of Geophysical Research: Oceans, 126, e2021JC017287.
1 6 . Chen, Z., Shi, J.* , & Li, C. (2021). Two types of warm blobs in the Northeast Pacific and their potential effect on the El Niño. International Journal of Climatology, 41, 2810 – 2827.
1 7 . Shi, J.* , Fedorov, A. V.*, & Hu, S. (2019). A sea surface height perspective on El Niño diversity, ocean energetics, and energy damping rates. Geophysical Research Letters, 47, e2019GL086742.
1 8 . Shi, J.* , Chen, Z., Ding, S., & Lu, Y. (2020). A Hot Blob Eastward of New Zealand in December 2019. Atmosphere, 11(12), 1267.
1 9 . Shi, J. * , Fedorov, A. V. , & Hu , S. ( 2019 ) . North Pacific temperature and precipitation response to El Niño - like equatorial heating: sensitivity to forcing location. Climate Dyn amics , 53(5 – 6) , 2731 – 2741.
20 . Shi, J. , & Qian , W*. ( 2018 ) . Asymmetry of two types of ENSO in the transition between the East Asian winter monsoon and the ensuing summer monsoon. Climate Dyn amics , 51(9 – 10) , 3907 – 3926.
21 . Shi, J. , & Qian , W*. ( 2016 ) . Connection between a nomalous z onal a ctivities of the South Asian h igh and Eurasian s ummer c limate a nomalies. J ournal of Climate, 29, 8249 – 8267 .
22 . 石剑 , 刘秦玉 . 2022 . 东北太平洋的暖泡和冷泡事件 . 海洋 - 大气相互作用研究进展 . 中 国海洋大学出版社 , 130 – 144 .
23 . 白燕 , 王欣宇 , 石剑 * , 郭浩康 2024 . 2020 – 2022 年与 2010 – 2012 年两个“二次变冷” La Ni ñ a 事件的特征与机制对比 . 中国海洋大学学报 ( 自然科学版 ), 54(4), 13 – 26.
合作 文章 :
1. Wu , S , Zhang, Y.*, Kosaka , Y ., Lin , X ., Yang, J., Gong , K ., Liu , Y ., Shi, J. , & Wang , X. (202 5 ). Tropical forcing of the Pacific Decadal Oscillation tied to central Pacific ENS O . Journal of Climate , in press .
2 . Shu, Q, Zhang, Y.*,
Yang, J., Wang, S., Shi, J. , Wang, X., & Lin, X. (2024). Wintertime atmospheric forcing of subtropical northeastern Pacific SST variability. Climate Dynamics, 62 , 10733 – 10746 .
3 . L uo, Y., Li, C., An, X., & Shi, J. (2024). Inter decadal variability of the warm Arctic - cold Eurasia: synergetic modulation by the Arctic Oscillation and Barents sea ice. Climate Dynamics. 62, 7417 – 7427.
4 . Ji, K., Yu, J., Li, J., Hu, Z., Tseng, Y., Shi, J. , Zhao, Y., Sun, C., & Ding, R*. (2024). Enhanced North Pacific Victoria mode in a warming climate. npj Climate and Atmospheric Science. 7, 49.
5 . D ong, L.*, Zeng, S., Song, F., Wu, L., Shi, J. , Ding, Y., & Lv, S. (2024). Roles of external forcing and internal variability in global marine heatwaves change during 1982 - 2021. Geophysical Research Letters, 51(4), e2023GL107557.
6 . Wang, S., Jing, Z.*, Wu, L., Sun, S. , Peng, Q., Wang, H., Zhang, Y., & Shi, J. (202 3 ). Southern hemisphere eastern boundary upwelling systems emerging as future marine heatwave hotspots under greenhouse warming . Nature Communications , 14, 28 .
7 . Luo, Y., Shi, J. , An, X. , & Li, C.* (202 2 ). The combined impact of subtropical wave train and Polar−Eurasian teleconnection on the extreme cold event over North China in January 2021 . Climate Dynamics, 60 , 3339 – 3352 .
8 . W ang , S., Jing, Z. * , Wu, L., Wang, H., Shi, J. , Che n, Z., Ma, X., Gan, B., Yang, H., & Liu, X. (2022). Changing ocean seasonal cycle escalates destructive marine heatwaves in a warming climate. Environmental Research Letters, 17, 054024.
9 . W ang , S., Jing, Z. * , Sun, D., Shi, J. , & Wu, L. (2022). A new model for isolating the marine heatwave changes under warming scenarios. Journal of Atmospheric and Oceanic Technology, 39, 1353 – 1366 .
10 . Qian, W. * , & Shi , J. ( 2017 ) . Tripole precipitation pattern and SST variations linked with extreme zonal activities of the western Pacific subtropical high. Int ernational J ournal of Climatol ogy , 37, 3018 – 3035.
11 . Qian, W. * , Wu, K. , Leung, J. C. - H. , & Shi , J. ( 2016 ) . Long - term trends of the Polar and Arctic cells influencing the Arctic climate since 1989. J ournal of Geophys ical Res earch : Atmo spheres , 121, 2679 – 2690.
12 . Luo, Y., Li, C.*, Shi, J. , An, X., & Sun, Y. (2021). Wintertime Cold Extremes in Northeast China and Their Linkage with Sea Ice in Barents - Kara Seas. Atmosphere, 12, 386.
13 . 王睿琪 , 李春 * , 石剑 , 于腾飞 . 2024 . 2022 年 5 月欧亚大陆中高纬度地区“三极子”型异 常气温的特点和成因 . 中国海洋大学学报 ( 自然科学版 ), 5 4( 12 ), 11 – 23 .
14 . 郭浩康 , 李春 * , 石剑 . 2024 . 江南 5 月降水与热带印度洋海温的年际联系 . 中国海洋大学 学报 ( 自然科学版 ), 5 4(5), 23 – 32 .
15 . 郭浩康 , 李春 * , 石剑 . 2024 . 近 2 0 年北大西洋中纬度海温与江南 5 月降水关系增强的可 能原因 . 中国海洋大学学报 ( 自然科学版 ), 54(03), 20 – 30 .
16 . 郭浩康 , 李春 * , 石剑 . 2023 . 2021 年 5 月江南持续强降水的准双周振荡及可能成因 . 中国 海洋大学学报 ( 自然科学版 ), 5 3(11), 11 – 23 .
17 . 孙亚卿 , 李春 *, 石剑 . 长江流域夏季极端高温的年代际变化特征及其与 AMO 的关系 . 2022. 中国海洋大学学报 ( 自然科学版 ), 52(2) , 13 – 22.
18 . 付强 , 石剑 , 徐梦阳 , 艾阳 , 钱维宏 *. 2022. 中国东北及邻近地区夏半年极端暖事件的时 空和环流特征分析 . 热带气象学报 , 38(1), 101 – 11 2.
19 . 于腾飞 , 李春 *, 石剑 . 2022. 郑州“ 7•20 ”极端暴雨的水汽输送特征 . 海洋气象学报 , 4 3(3) , 1 – 10.
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