葛旭阳

个人信息Personal Information

教授博士生导师硕士生导师

教师拼音名称：gexuyang

所在单位：大气科学学院

学历：博士研究生毕业

性别：男

学位：博士学位

职称：教授

博士生导师

硕士生导师

学科：大气科学

同专业博导同专业硕导

基本信息
个人简介
近期主要论著
近期科研项目

姓       名:  葛旭阳
出生年月:  1972年6月
国       籍:  中国
性       别:  男
职       称:  教授
最高学历:  博士
所属系部:  动力气象系
办公地点:  气象楼303室
邮       箱:  xuyang@nuist.edu.cn
主讲课程:  中尺度天气动力学
主要研究领域: 热带气旋动力学、中尺度气象学数值模拟

（^# 学生，* 通讯作者）

2025

Lv, L.Y^#., X. GE^*, M. Peng. 2025: Dynamic Vortex Initialization for Tropical Cyclone Predictions Utilizing PV-ω Equation and Nudging. Atmospheric Research, in revision.
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. In Press.
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. https://doi.org/10.1016/j.wace.2025.100770.
邓一君^#，陈明诚，葛旭阳. 雅鲁藏布江大峡谷区域两类降水过程传播差异成因分析. 大气科学学报，录用.
刘开源#，葛豪轩，姜有山，葛旭阳：台风“烟花”陆上长久维持成因分析. 气象科学, 录用
凌心雨^#, 刘开源^#, 葛旭阳*, 高珊. 2024: 双低空急流耦合对台风“杜苏芮”（2305）后部暴雨增幅作用. 大气科学学报，待刊
沈上骐^# ,黄绮君^#,葛旭阳*, 2025: “非典型对流”台风快速增强机制研究: 地表潜热通量作用. 大气科学, 493(3), doi:10.3878/j.issn.1006-9895.2310.23073
张彤彤，李涵，郝冰洁，童劲, 朱磊, 葛旭阳, 马旭林. 2025: 超强台风“利奇马”(1909)近海路径预报误差的关键影响机制. 气象学报. DOI: 10.11676/qxxb2025.20240168. 录用
张月^#, 葛旭阳^*. 2024: 2021年“4.30”南通地区大风形成机理及数值模拟. 气象科学, 2025,45(1):82-94, DOI: 10.12306/2022jms.0022.

2024

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. DOI: https://doi.org/10.1175/MWR-D-24-0077.1
Ling, J. W.^#, X. Ge^*, M. Peng, Q. Huang^#, 2024: Thermodynamical impacts on the boundary layer imbalance during secondary eyewall formation. Atmos. Res., 310(2024) 107610.
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. Env. Res. Lett., 19 (2024) 084003
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
赖子洋^#, 周玉淑, 葛旭阳^*，邓国. 2024: 四川盆地一次暴雨过程中的穿透性对流形成机理分析. 大气科学, 48(2):755-772. doi:10.3878/j.issn.1006-9895.2112.21174
刘开源^#、戴竹君、姜有山、黄绮君^#、葛旭阳. 2024: 台风“烟花”(2106)缓慢移动的机理研究：远距离双台风相互作用. 气象科学. 44(2):308-316.
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
黄玉蓉^#，黄绮君^#，郭炳瑶^#，葛旭阳^*，陈明诚. 2024: 季风低压诱发2018年8月广东特大暴雨过程分析. 大气科学学报，47(1):95-107

2023

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/10.1029/2023JD03
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. doi: 10.1007/s13351-023-3046-1
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
杨逸霖^#, 钱燕珍, 葛旭阳^*, 黄绮君^#. 2023:台风“黑格比”登陆期间浙江地区水汽演变特征分析. 热带气象学报，39(3):413-423.
庆涛，黄绮君^#，沈澄，朱磊，葛旭阳. 2023: 不同水汽环境条件下云凝结核浓度对热带气旋发展影响的数值研究. 气象科学, 43(3):305-315
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. Atmos. Sci., 40:1-17. https://doi.org/10.1007/s00376-022-2100-8.
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):4559-4569.
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.

2022

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
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.
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, https://doi.org/ 10.46267/j.1006-8775.2022.024
邓中仁^#、葛旭阳^*、姚秀萍、陈明诚, 2022: 短波辐射对高原涡形成和发展影响的模拟研究. 大气科学, 46(3):541-556. doi: 10.3878/j.issn.1006-9895.2105.20215.
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.
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. Frontier in Earth Science.DOI: 10.3389/feart.2021.832670.
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, DOI: 10.1002/JOC.7288.

2021

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. doi: 10.3389/feart.2021.739507.
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.
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.
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.

2020

陈兵，黄绮君^#，卢长浩，葛旭阳，苏爱芳，2020: 云分析方法在浙江省一次强对流天气过程数值模拟的应用初探. 气象科学, 40(6)：782-790.
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.
陈兵，黎璐^#，葛旭阳*，陈明诚，姜有山. 2020: 热带海温多时间尺度变化特征分析. 气象科学, 40(4): 475-484.
李箭^#, 葛旭阳*, 施东雷^#, 2020: 1991年8月季风涡旋个例形成的模拟研究.热带气象学报, 36(1): 72-84.
Li L.^#, and X. Ge*, 2020: Intensity change of tropical cyclone Noru (2017) during binary interaction. Asian-Pacific Journal of Atmospheric Science, 1-13.

2019

Shi, D. L. ^#, X. Ge*, M. Peng, and 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.6338，1-14. (IF=3.928)
Shi, D. L. ^#, X. Ge*, and M. Peng, 2019: Latitudinal Dependence of Dry Air Effect on Tropical Cyclone Intensification. Dynamics of Atmos. Oceans, 87, 1-15.
管靓^#，张宇昕^#，葛旭阳*，姜有山，2019：影响西北太平洋台风双眼墙生成的因子初步分析.大气科学学报. 42(4): 492-501.
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.
苏爱芳，施东雷^#，葛旭阳，2019:下垫面对郑州城市强降水的影响：城市化及地形影响的数值试验.大气科学学报，42（3）: 434-446.
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.
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

2018

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.
姜有山, 张高杰, 陈明诚, 葛旭阳. 2018: 23个CMIP5模式对厄尔尼诺事件生命史演变模拟能力的评估. 大气科学学报, 41(10).
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.
Ge, X.*, D. L. Shi^#, and L. Guan^#, 2018. Monthly variation of tropical cyclone rapid intensification ratio in the western North Pacific. Atmos. Sci. Lett., 19 (4):1-6. https://doi.org/10.1002/asl.814.
Ge, X.*, L. Guan^#, and Z. Yan^#, 2018: Impacts of Raindrop Evaporation on Tropical Cyclone Secondary Eyewall Formation. Dynamics of Atmospheres and Oceans, 82, 54-63.
葛旭阳*，许可^#，马悦^#，徐海明, 2018：云辐射强迫效应对热带气旋的影响研究. 大气科学学报, 41（1）: 46-54.
Guan, L^#., and X. Ge*, 2018:How does tropical cyclone initial size affect the secondary eyewall formation? J. Meteor. Res.,31(1): 124-134, doi: 10.1007/13351-018-7023-z.
Bi, M., X. Ge^*, and T. Li, 2018:Dependence of tropical cyclone intensification on the latitude under vertical shear. J. Meteor. Res., 32(1): 113-123, 10.1007/s13351-018-7055-4.

2017

Yan, Z. ^#, X. Ge*, and B.Y. Guo^#, 2017: Simulated sensitivity of tropical cyclone track to the moisture in an idealized monsoon gyre. Dynamics of Atmospheres and Oceans, 80(12), 173-182. doi.org/10.1016/j.dynatmoce.2017.10.008.
Ma, X., J. He, and X. Ge*, 2017: Simulated sensitivity of tropical cyclone eyewall replacement cycle to the ambient temperature profile. Adv. Atmos. Sci., 34(9), 1047 -1056. doi: 10.1007/s00376-017-6302-4.
Ge, X, W. Wang*, A. Kumar, and Y. Zhang, 2017: Importance of the vertical resolution in simulating SST diurnal and intra-seasonal variability in an oceanic general circulation model. J. Climate, 30(11), 3963-3978.
李艳*，周灏，葛旭阳，周伟灿，2017：西北太平洋迅速加强热带气旋的高空外流特征分析，热带气象学报，33（2）:145-154
徐威^#，周顺武*，葛旭阳，马悦，2017：西北太平洋热带气旋快速增强阶段的风速分布特征. 热带气象学报, 33（2）:259-266

2016

Ge, X^*, and L. Guan^#, S. W. Zhou. 2016: Impacts of initial structure of tropical cyclone on secondary eyewall formation. Atmos. Sci. Lett., 17，569-574.
Zhou, S. W., Y. Ma^#, and X. Ge^*, 2016: Impacts of diurnal cycle of solar radiation on spiral rainbands. Adv. Atmos. Sci.,33(9), 1085–1095.
徐梦婷^#，葛旭阳*，周顺武，等，2016：锋面涡旋诱发南海热带气旋Noguri(2002)的数值试验. 热带气象学报，32(3)，407-415.
徐梦婷^#，周顺武, 葛旭阳*, 2016：季风涡旋影响热带气旋发展的理想试验研究. 气象学报, 74 (5），733-743.
Xu, M. T^#, S. Zhou., and X. Ge ^*, 2016: An idealized simulation study of the impact of monsoon gyre on tropical cyclogenesis. Acta Meteorologica Sinica, 74(5), 81-91.
管靓^#，周顺武，葛旭阳*，王梅红, 2016：“育婴袋”假说在西北太平洋台风生成地点的应用研究. 热带气象学报，32(4), 494-502.

2015

Ge, X.*, W. Xu^#, S.W. Zhou, 2015: Sensitivity of tropical cyclone intensification on initial inner-core structure. Adv. Atmos. Sci., 32(10), 1407-1418.
Ge, X.*, Y. Ma^#, S.W. Zhou, and T. Li, 2015: Sensitivity of tropical cyclone warm-core on the solar radiation. Adv. Atmos. Sci., 32(8), 1038-1048.
Ge, X.*, 2015: The impacts of environmental humidity on concentric eyewall structure. Atmos. Sci. Lett., 16, 273-278.
Zhou, X., and X. Ge*, 2015. Tropical Cyclone Energy Dispersion and Possible Self-Maintenance Mechanism of the Synoptic-Scale Wave Trains. Meteorology and Environment Science, 38(1), 14-25.

2014

Ge, X.*, Y. Ma^#, S.W. Zhou, and T. Li, 2014: The impacts of diurnal cycle of radiation on tropical cyclone intensification and structure. Adv. Atmos. Sci., 31(6), 1377–1385.

2013

Ge, X., T. Li, and M. S. Peng, 2013: Effects of vertical shears and mid-level dry air on tropical cyclone developments. J. Atmos. Sci., 70(12), 3859-3875.
Ge, X., T. Li, and M. S. Peng, 2013: Tropical cyclone genesis efficiency: mid-level versus bottom vortex. J. Tropical Meteorology, 19 (3), 197-213.

2012

Li, T., X. Ge, M. S. Peng, and W. Wang, 2012: Dependence of tropical cyclone intensification on the Coriolis parameter. Tropical Cyclone Research and Review, 1(2), 242-253.
Zhang, S. J., T. Li, X. Ge, M. S. Peng, and N. Pan, 2012: A 3DVAR-based Dynamical Initialization Scheme for Tropical Cyclone Predictions. Weather forecasting, 27,473-483.

2011

Liang J., L. Wu, X. Ge, and C.-C. Wu, 2011: Monsoonal Influence on Typhoon Morakot (2009). Part II: Numerical Study. J. Atmos. Sci., 68, 2222–2235.
Hendricks, E. A., M. S. Peng, X. Ge, and T. Li, 2011: Performance of a Dynamic Initialization Scheme in the Coupled Ocean/Atmosphere Mesoscale Prediction System for Tropical Cyclones (COAMPS-TC), Wea. Forecasting, 26, 650–663
Zhou, X. Q., B. Wang, X. Ge, and T. Li, 2011: Response of Tropical Cyclone Intensity to Secondary Eyewall Heating. J. Atmos. Sci., 68, 450–456.

2010

Ge, X.^*, T. Li, S. Zhang, and M. S. Peng, 2010: What causes the extremely heavy rainfall in Taiwan during Typhoon Morakot (2009)? Atmos. Res. Lett., 11, 46–50.
Ge, X., T. Li, and M. Peng, 2010: Cyclogenesis simulations of Typhoon Prapiroon (2000) associated with Rossby wave energy dispersion. Mon. Wea. Rev., 138, 42–54.

2009

Peng, J., M. S. Peng, T. Li, and X. Ge, 2009: Barotropic instability in the tropical cyclone outer region. Q. J. R. Meteor. Soc., 135, 851 – 864.

2008

Ge, X., T. Li, Y. Wang, and M. S. Peng, 2008: Tropical cyclone energy dispersion in a three-dimensional primitive equation model: Upper tropospheric influence. J. Atmos. Sci., 65, 2272–2289.

2007

Ge, X.*, T. Li., and X. Zhou, 2007: Tropical cyclone energy dispersion under vertical shears. Geophys. Res. Lett., 34, L23807, doi:10.1029/2007GL031867.

2006

Li, T., X. Ge, B. Wang, and Y. Zhu, 2006: Tropical cyclogenesis associated with Rossby wave energy dispersion of a pre-existing typhoon. Part II: Numerical simulations. J. Atmos. Sci., 63, 1390–1409.

2003

Li, T., B. Fu, X. Ge, B. Wang, and M. S. Peng, 2003: Satellite data analysis and numerical simulation of tropical cyclone formation, Geophys. Res. Lett., 30, 2122, doi:10.1029/2003GL018556.

1998-2002

葛旭阳^*，李砚华，蒋尚城. 热带对流活动与长江中下游和华北地区夏季旱涝的关系. 南京气象学院学报, 2000, 23 (3), 391-398
葛旭阳^*，陶立英，朱永禔，李砚华. 青藏高原热力状况异常与长江中下游地区梅雨关系的相关分析及数值试验.应用气象学报, 2001, 12 (2), 159-166
葛旭阳^*，朱永禔. 青藏高原热力状况异常特征及其与长江中下游地区夏季降水的关系.气象科学, 2001, 21 (2), 147-153
周霞琼，葛旭阳，朱永禔. 影响华东地区热带气旋年频数与热带对流场的关系.气象科学, 2002, 22 (1), 9-15
葛旭阳^*，周霞琼，蒋尚城. 卫星双通道揭示的Walker环流活动特征及其与我国夏季降水关系初探.热带气象学报, 2002, 18 (2), 182-187
葛旭阳^*. 我国夏季降水对太平洋海温年代际变化响应的数值试验.南京气象学院学报, 2000, 23(4), 555-559
葛旭阳^*，周霞琼. 欧亚大陆雪盖月际变化特征及其与我国气候异常的关系初探.南京气象学院学报, 2002, 24 (2), 281-285
葛旭阳^*. 投影寻踪回归方法在长江三角洲地区降水量预报中的应用.气象科学, 2002, 24(1),88-92
朱乾根，葛旭阳，矫梅燕. 1976-1977年及1982-1983年厄尔尼诺事件过程差异的年代际背景.气象科学.1998, 18 (3), 203-213
葛旭阳^*，朱乾根，矫梅燕. 1976/1977年与1982/1983年El Nino事件的大气海洋特征.南京气象学院学报,1998, 21 (1), 53-60
葛旭阳^*，李砚华. 长江三角洲地区梅雨与青藏高原积雪关系初探．大气科学研究与应用. 1998, ( 1),122-125．
葛旭阳^*, 徐家良. BP人工神经网络在长江三角洲地区月、季降水预测中的应用. 大气科学研究与应用. 1998, ( 1), 126-131．

近期科研项目:

24. 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
23. 复杂环境下登陆热带气旋降雨精细结构特征和机理研究. 气象联合基金重点项目(U2342202). 骨干，2024.1-2027.12.
22. 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
21. CAS-FGOALS-F对中南半岛和华南地区极端降水事件模拟技巧检验评估. 大气物理研究所外协项目. 2021.7-2021.10
20. 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. 2019.1-2021.12
19. 云分析方法在淮河流域强对流事件中的应用研究. 2018年度淮河流域气象开放研究基金项目. 主持, 2019.3-2021.10
18. 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. 2019.6-2022.11
17. 通苏嘉甬铁路杭州湾跨海大桥气象观测与风参数专题研究之台风数值模拟.
16. 热带气旋虚拟仿真系统. 虚拟仿真实验教学培育项目. 主持
15. 江淮暖区暴雨预报技术研究及典型过程检验. 2018.4-2018.12.
14. 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.
13. 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.
12. 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)，参加，2018.1-2021.12.
11. 台风动力初始化方法的研制及其应用研究. 中国气象局气象关键技术集成与应用项目，参加，2016.1-2017.6.
10. 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.
9. 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), 参加, 2015.1-2017.12
8. 科技部973项目“登陆台风精细结构的观测、预报与影响评估”子课题：“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
7. 台风强度和结构演变机理及其预报技术的研究. 江苏省“六大人才高峰”第十一批高层次人才项目. 主持，2015.1-2017.12.
6. 河南省夏季农业致灾天气精细化预报技术研究. 中国气象局农业气象保障与应用技术重点开放实室开放研究基金，主持，2014.11-2016.10.
5. 登陆台风涡旋的中-Beta 结构及其演变的数值研究.中国气象科学研究院灾害天气国家重点实验室开放课题 , 参加，2014.7-2016.7
4. 台风登陆前后强度和风雨精细结构及其演变特征研究. 江苏省高校自然科学研究重大项目, 参加，2014.7-2017.7
3. Real-time convection-permitting ensemble analysis and predication of Atlantic hurricanes through assimilating airborne, radar and satellite observations. NOAA, HFIP project, Co-PI, 04/2011-05/2012.
2. “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, 2011/01/01 – 2013/12/31, 参加
1. 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, 2009/01/01 – 2011/12/31, 参加