中国·太阳集团城(古天乐)股份有限公司|官方网站

一、个人简介

葛旭阳，男，1972年6月生，教授，博士生导师。

美国夏威夷大学博士，先后在宾夕法尼亚州立大学/马里兰大学博士后和NOAA/NCEP访问学者，主要从事台风动力学与高影响致灾天气机理及预报研究。主持或参与各类科研与社会服务项目30余项，其中国家级项目10余项；发表核心以上学术论文100篇（其中SCI 60余篇），授权国家发明专利1项。

联系电话：15295739439

E-Mail: xuyang@jou.edu.cn

通讯地址：江苏省连云港市苍梧59号太阳集团城太阳集团城

二、研究方向

台风动力学；高影响致灾天气机理及预报技术；中尺度气象学及数值模拟。

三、教育经历

2002年7月—2008年6月：美国夏威夷大学，气象学，博士

1994年9月—1997年6月：南京气象公司，气象学，硕士

1990年9月—1994年6月：南京气象公司, 天气动力学，本科

四、工作经历

2025年11月—至今：太阳集团城，教授，博导

2013年9月—2025年10月：南京信息工程大学，教授，博导

2015年10月—2016年6月：NOAA/NCEP/CPC/ESSIC, 访问学者

2012年6月—2013年9月：夏威夷大学国际太平洋研究中心，博士后

2011年6月—2012年5月：NOAA/NCEP/EMC, UCAR访问学者

2010年10月—2011年5月：美国宾夕法尼亚州立大学，博士后

2008年6月—2010年10月：夏威夷大学国际太平洋研究中心，博士后

1997年7月—2002年6月：上海气候中心，工程师

五、社会兼职

2015年江苏省“六大人才高峰”高层次人才

国家自然科学基金、出版基金评审人

《气象与环境科学》编委 2025-2028

六、代表性科研项目

1. 云-辐射作用影响快速增强台风高层对流非对称性及强度演变机制.上海台风基金重点项目(TFJJ202402). 主持，2024.12-2026.11

2. 复杂环境下登陆热带气旋降雨精细结构特征和机理研究.国自然气象联合基金重点项目(U2342202). 骨干，2024.1-2027.12.

3. 垂直风切变下“非典型”台风强度快速变化的物理机制. 国家自然基金面上项目(42175003)，主持，2022.1-2025.12.

4. 基于气象保障的宁波港船舶调度关键技术提升及应用研究.宁波科技局重大攻关项目. 子课题负责人，2019-2021.

5. 24h警戒区登陆台风精细化和概率预报服务产品子系统：国家气象中心雷达工程. 主持，2019.4-2022.3

6. 重大灾害性天气的短时短期精细化无缝隙预报技术研究. 国家重点研发计划项目(2017YFC1502002), 骨干，2018.1-2022.12.

7. 青藏高原热力强迫影响西北太平洋热带气旋活动的机理研究. 国家自然基金重点项目(41730961)，骨干，2018.1-2022.12.

8. 高空外流特征及其对热带气旋强度与强度变化的影响. 国家自然基金面上项目(41775058)，骨干，2018.1-2021.12.

9. 台风双眼墙结构和强度变化研究. 国家自然基金面上项目( 41575056)，主持，2016.1-2019.12.

10. GRAPES区域集合预报多尺度混合扰动关键技术研究.公益性行业科研专项(201506007-02), 骨干, 2015.1-2017.12

11. 科技部973项目“登陆台风精细结构的观测、预报与影响评估”第3课题：“登陆台风精细化结构演变特征及其机理研究”（2015CB452803）,骨干，2015.1-2019.8

12. “袋鼠”理论在西北太平洋热带气旋生成中的应用研究. 国家自然基金面上项目（41075037）, 骨干，2011/01 – 2013/12

13. 低纬度中层涡旋诱发南海热带气旋形成的机制研究. 国家自然基金面上项目（40875026）, 骨干，2009/01 – 2011/12

七、代表性科研论文

(^#员工；*通讯作者)

[1] Wang, W. H^#., X. Ge*, M. Peng. 2025: Unusual Tropical Cyclone Tracks associated with Monsoon Gyre near an Isolated High Mountain. Atmospheric Research, 334 (2026) 108761.

[2] Li, H.^#, Z Wang, C. Davis; M. Peng; R. McTaggart-Cowan, X. Ge. 2025: Tropical Cyclogenesis under the Influence of an Upper Tropospheric Cold Low in Idealized Numerical Simulations. J. Atmos. Sci., 83(1):105-123.

[3] Lyu, L.Y^#., X. GE*, M. Peng. 2025: Dynamic Vortex Initialization for Tropical Cyclone Predictions Utilizing PV-ω Equation and Nudging. Atmospheric Research, 327(2026)108400.

[4] Wang, W. H^#., M. Peng, X. GE^*, M. Chen. 2025: Decadal variations of rapid intensification tropical cyclone ratios in the Northwest Pacific during autumn. Climate Dynamics. 63:253. DOI: 10.1007/s00382-025-07732-6.

[5] Zhang, J., Li, Q., Wu, L., Qian, Q., Ge, X., et al., 2025: Influence of Inner-core Symmetry on Tropical Cyclone Rapid Intensification and its Forecasting by a Machine Learning Ensemble Model. Weather and Climate Extremes.48, https://doi.org/10.1016/j.wace.2025.100770.

[6] Li, H^#, X. Ge*, M. Peng, Z. Wang. 2024: Impacts of an Upper-Tropospheric Cold Low on Tropical Cyclone Intensity. Mon. Wea. Rev.,152(12):2661-2677.

[7] Ling, J. W.^#, X. Ge*, M. Peng, Q. Huang#, 2024: Thermodynamical impacts on the boundary layer imbalance during secondary eyewall formation. Atmospheric Research, 310 (2024) 107610

[8] He, L. K., Q. L. Li, L. Wu, X. Ge, and et al., 2024: The impact of monsoon on the landfalling tropical cyclone persistent precipitation in South China. Environmental Research Letters. 19 (2024)084003.

[9] Lai, Z. Y., Y. S. Zhou, X. Ge, et al., 2024: Comparison of kinetic energy conversion characteristics of two extreme precipitation episodes during persistent unusually heavy rainfall on 17-23 July 2021 in Henan, China. Atmos. Res., 309(2024)107546. https://doi.org/10.1016/j.atmosres.2024.107546

[10] Li, H^#, Z. Yan^#, M. Peng, X. Ge*, Z. Wang, 2024: Unusual Tropical cyclone Tracks under the Influence of Upper Tropospheric Cold Low. Mon. Wea. Rev.,152(1):39-58. DOI: 10.1175/MWR-D-23-0074.1

[11] Ling, J. W.^#, X. Ge*, M. Peng, Q. Huang^#, 2023：Modulation of high-latitude tropical cyclone recurvature by solar radiation. Journal of Meteorological Research, 37(6): 802-811.

[12] Huang, Q. J.^#, X. GE*, 2023: Sensitivity of Tropical Cyclone Development to the Vortex Size under Vertical Wind Shear. JGR-atmosphere, 128, e2023JD038802. https://doi.org/10.1029/2023JD038802.

[13] Deng, Z. R. ^#, S.W. Zhou*, X. Ge*, Y. Qing, Y. Cheng. 2023: An Interdecadal Change in the Relationship between Summer Arctic Oscillation and Surface Air Temperature on the eastern Tibetan Plateau around the late 1990s. Climate Dynamics. DOI: 10.1007/s00382-023-06899-0

[14] Yan, Z. Y.^#, Z. Wang, M. Peng, and X. Ge. 2023: Polar Low Motion and Track Characteristics over the North Atlantic. J. Climate, 36(7):4550-4569. https://doi.org/10.1175/JCLI-D-22-0547.1.

[15] Du, X. G., H. S. Chen, Q. Q. Li, and X. Ge, 2023: Urban Impact on Landfalling Tropical Cyclone Precipitation: A Numerical Study of Typhoon Rumbia (2018). Adv. Atm. Sci. 40:1-17.

[16] Bi, M. Y., R. Wang, T. Li, and X. GE, 2023: Effects of vertical shear on tropical cyclones with different initial sizes. Frontiers in Earth Science. 11:1106204. doi: 10.3389/feart.2023.1106204.

[17] Huang Q. J.^#, B.Y. Guo^#, X. Ge*. 2022: Simulations of multiple Tropical cyclones event associated with the monsoon trough over the western North Pacific. Meteorological Applications, 29(6), e2104. https://doi.org/10.1002/met.2104.

[18] Li, H.^#, X. Ge*, M. Peng, and L. Li, 2022: The influences of Monsoon Trough on the relative motion of Binary Tropical Cyclones. J. Meteor. Soc. Japan, 100(5):729–749, doi:10.2151/jmsj.2022-038.

[19] Huang, Q. J.^#, X. GE*, M. Peng, and Z. R. Deng, 2022: Sensitivity analysis of the super heavy rainfall event in Henan on 20 July (2021) using ECMWF ensemble forecasts. J. Tropical Meteorology, 28(3): 308-325.

[20] Yu. H., C. Wang, X. Ge^#. 2022: Modulation of Pacific Sea surface temperatures on the late-season typhoon tracks and its implication for seasonal forecasting. Frontiers in Earth Science. DOI:10.3389/feart.2022.835001.

[21] Huang, Q. J.^#, X. Ge*, and M. Bi. 2022. Simulation of Rapid intensification of super Typhoon Lekima (2019). Part II: The critical role of cloud-radiation interaction of asymmetric convection. Frontiers in Earth Science. DOI: 10.3389/feart.2021.832670.

[22] Lu, C. H., X. GE*, M. Peng, and T. Li. 2022: Influence of El Niño decaying pace on low latitude tropical cyclogenesis over the western North Pacific. Int. J. Climatology, 1-11. https://doi.org/10.1002/joc.7288

[23] Huang, Q. J. ^#, X. Ge*, M. Peng, 2021: Simulation of Rapid Intensification of Super Typhoon Lekima (2019). Part I: Evolution characteristics of asymmetric convection under Upper-Level Vertical Shear. Frontiers in Earth Science. 9:739507. doi: 10.3389/feart.2021.739507

[24] Lu, C. H., X. GE*, and M. Peng 2021: Comparison of Controlling Parameters for the Formation of Near-Equatorial Tropical Cyclone between Western North Pacific and North Atlantic. Journal of Meteorological Research. 35(4): 623-634. doi: 10.1007/s13351-021-0208-x.

[25] He, J. X., Ma, X. Ge, et al. 2021: Variational Quality Control of Non-Gaussian Innovations in the GRAPES m3DVAR Model: Part II. Mass Field Evaluation of Conventional Observational Assimilation. Adv. Atmos. Sci., 38(6): 1510–1524.

[26] Yan, Z. Y.^#, X. Ge*, Z. Wang, C. C. Wu, and M. Peng. 2021: Understanding the impacts of upper-tropospheric cold low on typhoon Jongdari (2018) using Piecewise potential vorticity inversion. Mon. Wea. Rev., 149(5):1499-1515.

[27] Li L.^#, and X. Ge*, 2021: Intensity change of tropical cyclone Noru (2017) during binary interaction. Asian-Pacific Journal of Atmospheric Science, 57(1):135–147.

[28] Huang, Q. J.^#, X. Ge*, M. Peng, 2020: Impacts of upper easterly wave on the sudden track change of Typhoon Megi (2010). J. Meteor. Soc. Japan., 98(6), 1335-1352.

[29] Shi, D. L.^#, X. Ge*, and M. Peng, T. Li, 2019: Characterization of tropical cyclone rapid intensification under two types of El Niño events in the Western North Pacific. Int. J. Climatology, DOI: 10.1002/joc.6338

[30] Shi, D. L. ^#, X. Ge*, and M. Peng, 2019: Latitudinal Dependence of Dry Air Effect on Tropical Cyclone Intensification. Dynamics of Atmospheres and Oceans, 87, 1-15.

[31] Yan Z. Y. ^#, X. Ge*, M. S. Peng, and T. Li, 2019. Does Monsoon Gyre always favor Tropical Cyclone Rapid Intensification? Q. J. R. Meteor. Soc., 1-13. DOI: 10.1002/qj.3586.

[32] Cai, M., Y. Q. Wang*, and X. Ge, 2019: Simulated Spiral Rainbands in Typhoon Chanchu (2006): Model verification and Fine Rainband Structures. J. Tropical Meteorology, 25(2): 141-152.

[33] Ge, X.^*, and D. L. Shi^#, 2019: The Mid-latitudinal influences on the formation of the monsoon gyre in August 1991. Dynamics of Atmospheres and Oceans, 86，52-62.

[34] Guo, B.Y.^#, and X. Ge^*, 2018: Monsoon Trough Influences on Multiple Tropical Cyclone Events in the western North Pacific. Atmos. Sci. Lett., e851. https://doi.org/10.1002/asl.851.

[35] Ge, X*, Z. Yan^#, M. S. Peng, M. Bi, and T. Li, 2018. Sensitivity of Tropical Cyclone Track to the vertical structure of a nearby Monsoon Gyre. J. Atmos. Sci., 75(6), 2017-2028.

[36] Ge, X.*, D. L. Shi^#, and L. Guan^#, 2018. Monthly variation of tropic...