人才详细信息

姓名:孙咏
性别:
学历:博士
专家类别:副研究员
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传真:
电子邮箱:
职称:
通讯地址:

简介

理学博士,研究领域:古气候模拟、水体氧同位素模拟和气候动力学;现任深时气候模拟国际比较计划(DeepMIP)成员、中新世气候模拟国际比较计划(MioMIP2)成员和上新世气候模拟国际比较计划(PlioMIP)成员。截止目前,共发表学术论文45篇, 第一作者SCI(12篇),唯一通讯作者(1篇CEE),共同通讯作者(2篇:GPC,QI)。近期研究工作:
(1)聚焦中国夏季极端降水的能量约束机制
一个关键科学问题:在局地净能量输入有限甚至减弱的情况下,极端降水为何仍能维持持续而强烈的上升运动?
尽管既有研究已充分揭示水汽供应和热力条件的重要作用,但支撑这种持续强上升运动的能量来源仍是一个关键未解问题。研究发现,极端降水并不能完全由更强的水汽供应来解释,还受到跨区域能量输送和天气尺度动力过程的重要控制。中纬度瞬变扰动向季风区输送干焓能量,从而维持更强的上升运动,并重组水汽输送结构。该研究揭示了维持东亚极端降水持续强上升运动的关键能量来源(Yuan…& Sun 2026, CEE)。
(2)鉴于始新世东亚季风是否存在仍存争议,且古地理边界条件是古气候模拟的关键不确定性来源,我们依据最新地质证据对原有始新世边界条件进行了区域修正,重点更新了印–欧碰撞时间、碰撞方式,并纳入了“两山夹一盆”区域古高度重建,开展了早、晚始新世气候模拟。结果表明,早晚始新世均未出现现代意义上的东亚季风(Sun and Ding 2026, AOSL);
(3)针对海洋快速升温的气候影响,基于大规模数值试验,开展了未来哈德莱环流变化的区域海盆归因。研究首次明确,热带印度洋升温在未来哈德莱环流强度减弱及边界向极扩展中的主导作用,而热带太平洋升温则是其未来预估不确定性的主要来源(Sun et al. 2025, NSR);
(4)针对如何实现“记录和模拟融合”,开展了季风降水物理过程分解协调记录和模拟比较的新尝试,并将该思路用于理解新生代以下关键片段:晚上新世(Sun et al. 2024, npjCAS)、末次冰盛期(Sun et al. 2021, Climate Dynamics)和中全新世(Sun et al. 2023, Climate Dynamics)记录和模拟的比较;
(5)完成了新近纪关键片段(中中新世和晚上新世)降水氧同位素模拟及解译(Sun et al. 2024, Paleo-3; Sun et al. 2024, Climate Dynamics)。

学习经历

(1)2009年09月—2014年07月, 中国科学院大气物理研究所,气象学,博士研究生

2012年04月—2013年04月,法国气候与环境科学实验室(LSCE),中法联合培养博士研究生,古气候模拟,法方导师:Ramstein Gilles教授

(2)2005年09月—2009年07月,云南大学,大气科学系,本科

工作经历

2022年02月至今, 中国科学院青藏高原研究所TPESER全国重点实验室,副研究员

2014年07月—2022年01月, 中国科学院大气物理研究所LASG 国家重点实验室,助理研究员

2019年07月—2020年01月,LSCE 访问学者   

2018年12月—2019年02月,LSCE 访问学者   

2016年09月—2018年09月,LSCE,博士后  

研究方向

构造—气候环境相互作用、轨道尺度的季风动力学、热带大气动力学、行星大气数值模拟

职务

社会任职

承担项目

获奖及荣誉

代表论著

论文发表清单(*为通讯作者)

2026年

  1. Yuan, X., Su, B., Liu, B., Liu, J., Zhang, Y., Li, Z., Peng, D.,Sun, Y*. Transport-constrained eddy–mean energetics sustain extreme rainfall over China. Commun Earth Environ 7, 443 (2026). https://doi.org/10.1038/s43247-026-03547-3
  2. Sun, Y*., Ding, L*., 2026. Modeling Eocene Asian climate with geologically revised paleogeography. Atmospheric and Oceanic Science Letters 19, 100814. https://doi.org/10.1016/j.aosl.2026.100814
  3. Su, B., Sun, Y. and Han, S. (2026). 'Drivers of the Earth’s interhemispheric temperature gradient through the Phanerozoic Eon', Atmospheric and Oceanic Science Letters, 100824. doi: 10.1016/j.aosl.2026.100824.
  4. Fang, J., Zhang, Y., Hauglustaine, D., Zheng, B., Wang, M., Li, J., Sun, Y., Li, H., Wang, J., Wu, Y., Yuan, B., Chen, M., and Ge, X.: Tracking surface ozone responses to clean air actions under a warming climate in China using machine learning, Atmos. Chem. Phys., 26, 851–867, https://doi.org/10.5194/acp-26-851-2026, 2026.
  5. 丁林, 熊中玉, 田小龙, 何松林, 赵晨圆, 平凡,孙咏,曾登, 左亮, 任静怡, 王厚起, 蔡福龙, 王超. 从造山带到青藏高原的隆升: 质演化与气候变化的机理连通性. 科学通报, 2026.71: 494–517.https://doi.org/10.1360/CSB-2025-0639

2025年

  1. SunY*, Gilles Ramstein, Alexey V Fedorov, Lin Ding, Bo Liu (2025). Tropical Indian Ocean drives Hadley circulation change in a warming climate, National Science Review, nwae375, https://doi.org/10.1093/nsr/nwae375
  2. Zhang, K., Sun, Y.*, Jiang, Y., Guo, H., Lin, J., Chen, J., & Wang, X*. (2025). Tropical circulation shifts and regional climate impacts: Comparing mid-Piacenzian warmth and future warming (SSP2–4.5). Global and Planetary Change.Global and Planetary Change,253, 104941,https://doi.org/10.1016/j.gloplacha.2025.104941
  3. Su, B., Sun, Y. & Zhou, M. Orbital-accelerated transient simulations of glacial-interglacial climate cycles for the last 800,000 years. Sci Data12, 961 (2025). https://doi.org/10.1038/s41597-025-05297-x
  4. Su B, Sun Y. 2025. Simulation of the climatic conditions required for the existence of ice sheet on the Tibetan Plateau. Glob Planet Change. 257:105202. https://doi.org/10.1016/j.gloplacha.2025.105202
  5. Chen, L., Wu, H., Sun, Y., Jia, Y., Zhang, W., Tian, L., et al. (2025). Spatial patterns and mechanisms of the temperature response in East Asia to mid-Piacenzian warming. Journal of Geophysical Research: Atmospheres, 130, e2025JD044313. https://doi.org/10.1029/2025JD044313
  6. Gowan, E.J., Tomita, T., Nishioka, D., Zhang, X., Sun, Y. et al. Impact of topographic change on the East Asian monsoon in Japan and Eastern Asia during the Last Glacial Maximum. Prog Earth Planet Sci 12, 18 (2025). https://doi.org/10.1186/s40645-024-00681-4
  7. 孙咏*, 吴海斌, 苏宝煌, 秦小光, 谭宁, 丁林, MILLOUR Ehouarn. 火星地形对大尺度气候影响的模拟研究: 基于LMD.MARSLMD_MM_MARS模式的全球和区域加密模拟[J]. 第四纪研究, 2025, 45(4): 831-838. doi: 10.11928/j.issn.1001-7410.2025.04.01. 
  8. 苏宝煌,孙咏, 吴海斌. MarsCAM模拟的火星地形对地表温度影响机制研究[J]. 第四纪研究, 2025, 45(4): 839-849. doi: 10.11928/j.issn.1001-7410.2025.04.02.
  9. 宗思翰, 谭宁, 赵明宇, 陈凌, 吴海斌, 孙咏, 林巍, 郭正堂. 火星早期气候模拟研究:回顾与展望[J]. 第四纪研究, 2025, 45(4): 1001-1012. doi: 10.11928/j.issn.1001-7410.2025.04.16.

2024年

  1. Sun, Y*., Wu, H., Ding, L., Chen, L., Stepanek, C., Zhao, Y., Tan, N., Su, B., Yuan, X., Zhang, W., Liu, B., Hunter, S., Haywood, A., Abe-Ouchi, A., Otto-Bliesner, B., Contoux, C., Lunt, D., Dolan, A., Chandan, D., Lohmann, G., Dowsett, H., Tindall, J., Baatsen, M., Peltier, W., Li, Q., Feng, R., Salzmann, U., Chan, W., Zhang, Z., Williams, C., Ramstein, G. (2024). Decomposition of physical processes controlling EASM precipitation changes during the mid-Piacenzian: new insights into data–model integration. npj Clim Atmos Sci 7, 120 (2024). https://doi.org/10.1038/s41612-024-00668-4
  2. Sun, Y.*, Ding, L., Su, B., Dowsett, H., Wu, H., Hu, J., Stepanek, C., Xiong, Z., Yuan, X., Ramstein, G. (2024). Modeling the mid-Piacenzian warm climate using the water isotope-enabled Community Earth System Model (iCESM1.2-ITPCAS). Climate Dynamics 62, 7741–7761 (2024). https://doi.org/10.1007/s00382-024-07304-0.
  3. Sun, Y.*, Ding, L., Su, B., Stepanek, C., &Ramstein, G. (2024). Simulating surface warming in Earth's three polar regions during the Middle Miocene Climatic Optimum using isotopic and non-isotopic versions of the Community Earth System Model. Palaeogeography, Palaeoclimatology, Palaeoecology.643, 112156. https://doi.org/10.1016/j.palaeo.2024.112156
  4. Zhang, K., Sun, Y*., Zhang, Z., Stepanek, C., Feng, R., Hill, D., Lohmann, G., Dolan, A., Haywood, A., Abe-Ouchi A., Otto-Bliesner, B. L., Contoux, C., Chandan, D., Ramstein G., Dowsett, H., Tindall, J., Baatsen, M., Tan, N., Peltier, W. R., Li, Q., Chan, W.-L., Wang, X., Zhang, X*. Revisiting the physical processes controlling the tropical atmospheric circulation changes during the Mid-Piacenzian Warm Period.Quaternary International.682, 46-59 (2024).https://doi.org/10.1016/j.quaint.2024.01.001
  5. Liang, M.-Q., Yin, Q., Sun, Y., Zhang, C., Berger, A., Lyu, A., Liu, W. & Wu, Z.Distinct response of Asian summer monsoon circulation and precipitation to orbital forcing during six Heinrich events.Quaternary Science Reviews344, 108946 (2024).https://doi.org/10.1016/j.quascirev.2024.108946
  6. Zuo, M., Sun, Y., Zhao, Y., Ramstein, G., Ding, L., and Zhou, T.: South Asian summer monsoon enhanced by the uplift of the Iranian Plateau in Middle Miocene, Clim. Past, 20, 1817–1836, https://doi.org/10.5194/cp-20-1817-2024, 2024.Zuo, M., Sun, Y., Zhao, Y., Ramstein, G., Ding, L., and Zhou, T.: South Asian summer monsoon enhanced by the uplift of the Iranian Plateau in Middle Miocene, Clim. Past, 20, 1817–1836, https://doi.org/10.5194/cp-20-1817-2024, 2024.
  7. Tan, N., Li, H., Zhang, Z., Wu, H., Ramstein, G., Sun, Y., He, Z., Su, B., Zhang, Z., & Guo, Z. (2024). Closure of tropical seaways favors the climate and vegetation in tropical Africa and South America approaching their present conditions. Global and Planetary Change 233, 104351. https://doi.org/10.1016/j.gloplacha.2023.104351

2023年

  1. Sun, Y.*, H. Wu, G. Ramstein, B. Liu, Y. Zhao, L. Z. X. Li, X. Y. Yuan, W. C. Zhang, L. J. Li, L. W. Zou, T. J. Zhou.2023. Revisiting the Physical Mechanisms of East Asian Summer Monsoon Precipitation Changes During the Mid-Holocene: A Data–model Comparison. Climate Dynamics 60, 1009–1022 (2023). https://doi.org/10.1007/s00382-022-06359-1.
  2. Liu, J., Qin, X., Ren, X., Wang, X., Sun, Y., Zeng, X., Wu, H., Chen, Z., Chen, W., Chen, Y., Wang, C., Sun, Z., Zhang, R., Ouyang, Z., Guo, Z., Head, J.W., & Li, C. (2023). Martian dunes indicative of wind regime shift in line with end of ice age. Nature, 620, 303 - 309. https://doi.org/10.1038/s41586-023-06206-1
  3. Qin, X., Ren, X., Wang, X., Liu, J., Wu, H., Zeng, X., Sun, Y., Chen, Z., Zhang, S., Zhang, Y., Chen, W., Liu, B., Liu, D., Guo, L., Li, K., Zeng, X., Huang, H., Zhang, Q., Yu, S., Li, C., & Guo, Z. (2023). Modern water at low latitudes on Mars: Potential evidence from dune surfaces. Science Advances, 9. eadd8868(2023).DOI:10.1126/sciadv.add8868
  4. Chen, Y., Liu, B., Luo, Y., Martinez-Villalobos, C., Ren, G., Huang, Y., Zhang, S., Sun, Y., & Zhang, Z. (2023).Relative contribution of moisture transport during TC-active and TC-inactive periods to the precipitation in Henan Province of North China: Mean state and an extreme event.Journal of Climate, 36(11), 3611–3623.https://doi.org/10.1175/JCLI-D-22-0582.1
  5. 熊力, 刘博*, 孙咏*. 末次间冰期全球地表温度变化及物理机制的模拟研究[J].第四纪研究, 2023, 43(4): 1010-1018. doi: 10.11928/j.issn.1001-7410.2023.04.09
  6. 苏宝煌, 孙咏. 青藏高原区域抬升对轨道尺度亚洲季风调制效应的模拟研究[J]. 第四纪研究, 2023, 43(4): 940-951. doi: 10.11928/j.issn.1001-7410.2023.04.03

2022年

  1. He, S., Ding, L., Xiong, Z., Spicer, R.A., Farnsworth, A.J., Valdes, P.J., Wang, C., Cai, F., Wang, H., Sun, Y., Zeng, D., Xie, J., Yue, Y., Zhao, C., Song, P., & Wu, C. (2022). A distinctive Eocene Asian monsoon and modern biodiversity resulted from the rise of eastern Tibet.Science bulletin, 67 (21), 2245-2258.
  2. Zhang W, Wu H, Cheng J, Geng J, Li Q, Sun Y, Yu Y, Lu H, Guo Z. Holocene seasonal temperature evolution and spatial variability over the Northern Hemisphere landmass. Nat Commun. 2022 Sep 10;13(1):5334. doi: 10.1038/s41467-022-33107-0.
  3. PengD. D., T. J. ZhouY. Sun, A. L, Lin. 2022, Interannual Variation in Moisture Sources for the First Rainy Season in South China Estimated by the FLEXPART Model. Journal of Climate.35(2): 745–761.

2021

  1. Sun, Y.*, H. Wu, M. Kageyama, G. Ramstein, L. Z. X. Li, N. Tan, Y. T. Lin, B. Liu, W. P. Zheng, W. C. Zhang, L. W. Zou, T. J. Zhou.2021. The contrasting effects of thermodynamic and dynamic processes on East Asian summer monsoon precipitation during the Last Glacial Maximum: a data-model comparison. Climate Dynamics.56, 1303–1316.
  2. Zhou, T. J., B. Wang, Y. Q. Yu, Y. M. Liu, W. P. Zheng, L. J. Li, B. Wu, P. F. Lin, Z. Guo, W. M. Man, Q. Bao, A. M. Duan, H. L. Liu, X. L. Chen, B. He, J. D. Li, L. W. Zou, X. C. Wang, L. X. Zhang, Y. Sun, W. X. Zhang. 2018. The FGOALS climate system model as a modeling tool for supporting climate sciences: An overview. Earth and Planetary Physics.2(4): 276– 291.

2020年

  1. Hopcroft, P., Ramstein G., T. A. M. Pugh, S. J. Hunter, F. Murguia-Flores, A. Quiquet, Y. Sun, N. Tan, P. J. Valdes. 2020.. Polar amplification of Pliocene climate by elevated trace gas radiative forcing. Proceedings of the National Academy of Sciences. 117 (38): 23401-23407.
  2. Tan, N., C. Contoux, G. Ramstein, Y. Sun, C. Dumas, P. Sepulchre, Z. T. Guo. 2020. Modeling a modern-like pCO2 warm period (Marine Isotope Stage KM5c) with two versions of an Institut Pierre Simon Laplace atmosphere–ocean coupled general circulation model. Climate of the Past. 16, 1–16.

2019年

  1. Sun, Y.*, L.Z.X. Li, G. Ramstein, T. J. Zhou, N. Tan, M. Kageyama, S. Y. Wang.  2019. Regional meridional cells governing the interannual variability of the Hadley circulation in boreal winter.Climate Dynamics.52, 831–853.
  2. 郑伟鹏, 满文敏, 孙咏.栾贻花. 2019. 第四次国际古气候模拟比较计划(PMIP4)概况与评述.气候变化研究进展.15 (5): 510-518.

2018年

  1. Sun, Y.*, G. Ramstein, L. Z. X. Li, C. Contoux, N. Tan, T. J. Zhou. 2018.Quantifying East Asian summer monsoon dynamics in the ECP4.5 scenario with reference to the midPiacenzian warm period. Geophysical Research Letters,45: 12,523–12,533.
  2. 孙咏*,周天军, 吴波.2018. 耦合气候系统模式FGOALS-s2 海洋数据同化试验模拟的冬季Hadley环流长期变化趋势. 科学通报. 63(4): 452-460.

2017年

  1. Yao, J. C., T. J. Zhou, Z. Guo, X. L. Chen, L. W. Zou, Y. Sun. 2017. Improved Performance of High-Resolution Atmospheric Models in Simulating the East Asian Summer Monsoon Rain Belt.Journal of Climate.30, 8825–8840.
  2. Zhou, T. J., X. L. Chen, B. Wu, Z. Guo, Y. Sun, L. W. Zou, W. M. Man, L. X. Zhang, C. He. 2017. A Robustness Analysis of CMIP5 Models over the East Asia-Western North Pacific Domain. Engineering.3: 773-778.

2016年

  1. Sun, Y., T. J. Zhou, G. Ramstein, C. Contoux, Z. S. Zhang. 2016. Drivers and mechanisms for enhanced summer monsoon precipitation over East Asia during the mid-Pliocene in the IPSL-CM5A. Climate Dynamics. 46, 1437–1457.2015
  2. Wu, B., X. L. Chen, F. F. Song, Y. Sun, T. J. Zhou. 2015. Initialized Decadal Predictions by LASG/IAP Climate System Model FGOALS-s2: Evaluations of Strengths and Weaknesses. Advances in Meteorology. 2015, 1-12.

2014年以前

  1. Sun, Y., T. J. Zhou. 2014. How Does El Niño Affect the Interannual Variability of the Boreal Summer Hadley Circulation?. Journal of Climate.27, 2622–2642.
  2. Sun, Y.*, G. Ramstein*, C. Contoux, T. J. Zhou. 2013. A comparative study of large-scale atmospheric circulation in the context of a future scenario (RCP4.5) and past warmth (mid-Pliocene). Climate of the Past.9, 1613-1627.
  3. Sun, Y., T. J. Zhou., L. X. Zhang. 2012. Observational analysis and numerical simulation of the interannual variability of the boreal winter Hadley circulation over the recent 30 years.Science China Earth Sciences.55, 1–15.孙咏,周天军, 张丽霞.2013.决定北半球冬季哈得莱环流年际变率的三维大气环流图像:观测分析和数值模拟.中国科学:地球科学.43(002):192-208.