周文博士长期从事东亚季风活动、极端高温事件、旱涝灾害和水汽输送,以及台风的研究,取得了一系列创新性的研究成果,这些成果不仅有重要科学意义,也有助于提高我国短期气候预测水平,并为国家制定抗震减灾政策提供了科学的依据。在季风活动和我国极端天气研究方面,不仅揭示了夏季风在南海爆发所呈现的多尺度变化特征,以及对可预测性的影响;同时还研究了我国极端高温天气和寒潮的发生特征和成因, 针对严重影响我国的旱涝问题,研究了东亚地区的水汽输送变化规律,为年际和年代际气候预测提供了科学依据。还研究揭示了热带季节内振荡和ENSO对西北太平洋台风活动的调控作用和相关机理.
周文博士主持过多项国内、国际合作科研项目,如多项国家自然科学基金面上课题、香港GRF基金、澳门政府计划基金、德国/香港联合基金和法国/香港联合基金等。已出版发表135余篇SCI论文,SCI总引用高达2443余次, H 研究指数27;是国际地球科学前沿学术期刊Frontier in Earth Science以及国内大气科学学术期刊Advances in Atmospheric Science和高原气象的编委,香港气象学报的主编;并是Nature geoscience, Nature communication, Scientific Reports, Journal of Climate, Climate Dynamics, Journal of Geophysical Research等多个国际学术期刊的审稿人。周文博士于2008年获得德国洪堡学者称号(Alexander von Humboldt Research Fellow),并受聘为香港天文台科学顾问(Scientific Advisor,2008-2018),中国气象局热带海洋研究所的特聘教授(2014-2018)和中国科学院南海海洋研究所“创新国际团队”特聘专家(2014-2017),中国科学院大气物理研究所特聘教授(2013-2017),中国气象学会动力气候委员会委员,香港气象学会理事。2017年香港城市大学首届Top10优秀博士导师奖。
主要研究气候变异以及极端天气的机理研究。南海夏季风的变化规律及其可预测性研究
东亚夏季风一般(指出如果振荡位相一致时,南海夏季风环流在季节尺度上可预报性增强,反之可预报性减弱。
(气候变异以及极端天气的机理研究
提出乌拉尔山阻塞高压是导致2008年1月中国南方的主要原因之一,并北极涛动和ENSO对我国机率有共同影响,2篇文章被SCI引用近―“出口区“末端区3)多时间尺度东亚夏季风减弱导致的偏南风水汽输送减少,以及南北两个反气旋的外围环流引起水汽在华南的强烈辐合是造成两次突变的直接原因。两次过程中,经向的水汽输送变异比纬向的更为重要,且主要由低层风场异常导致。年际尺度上,东亚季风区夏季水汽环流主要受西太副高影响,其影响;并发现ENSO与东亚水汽环流的两个主要模态存在季节尺度上,我国西南、东南的水汽环流存在明显差异:西南主要由纬向水汽输送控制,东南则主要由经向水汽输送支配。各个季节,中国的响应都有亚太地区水汽输送的多时间尺度特征及其影响,极大地丰富了科学认知,受到广泛重视。
4)变化规律及机理研究
提出西北太平洋台风活动异常与热带季节内振荡(MJO)和MJO对热带气旋生成的调控作用加强,而在拉尼娜年的调控作用则较弱,并揭示出其中的过程和机理;进一步诊断MJO和ENSO对不同强度的热带气旋(超强台风、台风、热带风暴/热带低压)关系。研究发现南海台风在1994-2002年期间非常活跃的原因是因为北印度洋较冷和西太平洋较暖的负纬向海温梯度引起海水表面西风加强,有利于南海上空水汽辐合及MJO的发展。北印度洋和西太平洋纬向海温梯度变化在一定程度上决定了夏季南海台风的年际-年代际变化规律。这些研究有助于理解在全球变暖背景下,影响我国台风的变化以及提高对台风的预测水平。
2017 香港城市大学优秀博士导师奖
2017广州市科技一等奖
2017深圳市科学技术奖<span letter-spacing:-0.15pt;font-size:11pt;=>
2011 深圳虚拟大学科学技术奖
2008 德国洪堡学者
2006 王宽诚博士后研究奖
I 书籍及章节
1. Zheng C.W., Z.N. Xiao, W. Zhou, X.B. Chen, and X.Chen, 2017: The Maritime Silk Road- A Great Peaceful Way Forward. In Press.
2. Wang DX., X Wang, W. Zhou, C. Y. Li, 2014: Comparisons of Two Types of El Niño Impacts on TC Genesis over the South China Sea. January 2014. DOI: 10.1007/978-3-642-40695-9_17. In book: Typhoon Impact and Crisis Management, pp.351-359
II 已发表SCI论文目录(* 通讯作者)
2018
1. Leung Y T, S. Qiu, and W Zhou*,2018: Modulations of rising motion and moisture on summer precipitation over the Yangtze River region. Climate Dynamics (Accepted)
2. Leung YT. W Zhou*, CM. Shun, P W Chan, 2018: Large-scale circulation control of the occurrence of low-level turbulence at HKIA. AAS (In press)
3. Wang L., G. Huang, W. Chen, W. Zhou and W.Q. Wang, 2018: Wet-to-dry shift over Southwest China in 1994 tied to the warming of tropical warm pool. Clim. Dyn., doi:10.1007/s00382-018-4068-8
4. Qian, C., W. Zhou, X.-Q. Yang and J. C. L. Chan, 2018: Statistical prediction of non-Gaussian climate extremes in urban areas based on the first-order difference method, Int. J. Climatol. DOI:10.1002/joc.5464.
5. Cheung H.N., Noel Keenleyside, N-E Omrani, W Zhou, 2017: Remarkable link between projected uncertainties of Arctic sea ice decline and winter Eurasian climate. AAS, 35, 38-51.
2017
6. Abolude Akintayo T., W. Zhou*, Y T Leung, 2017: Regional impact Assessment of monsoon variability on wind power availability and optimization in Asia. Atmosphere, 8,219. doi:10.3390/atmos8110219
7. Leung Y T,W Zhou*, 2017: Circumglobal teleconnection and eddy control of variation in summer precipitation over Northwest China. Climate Dynamics. doi 10.1007/s00382-017-3958-5
8. Zhou W*, 2017: The impact of Arctic Amplification on East Asian winter climate. Atmospheric and Oceanic Science Letters. doi: 10.1080/16742834.2017.1350093
9. Zhang, Z.X., W. Zhou, M. Wenig, and L.Yang,2017: Impact of long-range desert dust transport on hydrometeor formation over coastal East Asia. Adv. Atmos. Sci., 34, 101-105.
10. Leung Y. T., H. N. Cheung, and W. Zhou*, 2017: Meridional Displacement of the East Asian Trough and Its Response to ENSO Forcing. Climate Dynamics. 48, 335-352. doi: 10.1007/s00382-016-3077-8
11. Wang W. W., W. Zhou*, 2017: Statistical modeling and trend detection of extreme sea level records in the Pearl River Estuary, Adv. Atmos. Sci., 34,383-396.
12. Li C.Y., W. Zhou*, C. M. Shun, T. C. Lee, 2017: Change in destructiveness of landfalling tropical cyclones over China in recent decades. J. Climate. 30, 3367-3379.
13. Li X.Z., Y.Q. Chen and W. Zhou, 2017: Response of winter moisture circulation to the India-Burma Trough and its modulation by the South Asian waveguide. J. Climate. 30, 1197-1210.
14. Lin X B, ZP Wen, W. Zhou, R. G. Wu, 2017: Effects of Tropical Cyclone Activity on the Boundary Moisture Budget over Eastern China Monsoon Region. Adv. Atmos. Sci., 34,700-712.
15. Xiao F. A., L.L. Zeng, Qin‑Yan Liu, W. Zhou and D.X. Wang, 2017: Extreme subsurface warm events in the South China Sea during 1998/99 and 2006/07: observations and mechanisms. Climate Dynamics. doi 10.1007/s00382-017-3588-y (In press)
16. Li G., J. Chen, X. Wang, X. Luo, D. Yang, W. Zhou, Y. Tan, H. Yan, 2017: Remote impact of North Atlantic sea surface temperature on rainfall in southwestern China during boreal spring. Climate Dynamics. doi 10.1007/s00382-017-3625-x (In press)
17. Chen Jie Peng, X Wang, W Zhou, ZP Wen, 2017: Interdecadal change in the summer SST-precipitation relationship around the late 1990s over the South China Sea. Climate Dynamics. doi 10.1007/s00382-017-4009-y (In press)
2016
1. Cheng. H. N., W. Zhou*, Y. T. Leung, CM. Shun, S.M. lee, H. W. Tong, 2016: A Strong Phase Reversal of the Arctic Oscillation in Midwinter 2015/16: Role of the Stratospheric Polar Vortex and Tropospheric Blocking. J. Geophys. Res. Atmos. DOI: 10.1002/2016JD025288.
2. Zhou W.*, C. Y. Li and C. H. Chow, 2016: Intraseasonal variation of visibility in Hong Kong, Advances in Atmospheric Sciences. 34, 26-38.
3. Leung Y. T., and W. Zhou*, 2016: Direct and indirect ENSO modulation of winter temperature over the Asian–Pacific–American region, Scientific Reports. DOI: 10.1038/srep36356
4. Zhang, Z., W. Zhou, M. Wenig, L.G. Yang, 2016: Impact of long-range desert dust transport on coastal East Asia: analysis of urban dust concentration and wet deposition with model simulation. Air Qual Atmos Health. 10, 325-337. doi:10.1007/s11869-016-0440-1.
5. Feng T. X.Q. Yang, W. Zhou, R. H. Huang, L. Wu and D. J. Yang, 2016: Synoptic-scale waves in sheared background flow over the western North Pacific. J. Atmos. Sci., 73, 4583-4603.
6. Cheung H.N., and W. Zhou*, 2016: Simple Metrics for Representing East Asian Winter Monsoon Variability: Ural Blocking and Western Pacific Teleconnection Pattern. Advances in Atmospheric Sciences, 33, 695-705.
7. Wang W.W., W. Zhou*, Eward Y.Y. Ng, 2016: Urban heat islands in Hong Kong: Statistical modeling and trend detection. Natural Hazards, 83, 885-907.
8. Li, X. Z., W. Zhou*, and Y. Q. Chen, 2016: Detecting the origins of moisture over Southeast China: Seasonal variation and extreme rainfall. Adv. Atmos. Sci. 33, 319-329.
9. Wang, L., W. Chen, W. Zhou, and G. Huang, 2016: Understanding and detecting Super- Extreme Droughts in Southwest China through an integrated approach and index, Quarterly Journal of the Royal Meteorological Society, 142, 529-535. doi: 10.1002/pi.2593.
10. Li, X. Z., and W. Zhou*, 2016: Modulation of the Interannual Variation of the India-Burma Trough on the Winter Moisture Supply over Southwest China. Climate Dynamics, 46, 147-158. doi:10.1007/s00382-015-2575-4.
11. Leung, Y. T., and W. Zhou*, 2016: Eddy contributions at multiple timescales to the evolution of persistent anomalous East Asian trough. Climate Dynamics. 46, 2287-2303. doi 10.1007/s00382-015-2702-2
12. Wang, W. W., W. Zhou*, X. Z. Li, X. Wang, and D. X. Wang, 2016: Synoptic-scale characteristics and atmospheric controls of summer heat waves in China. Climate Dynamics. 46, 2923-2941. Doi: 10.1007/s00382-015-2741-8
13. Wang, L., G. Huang, W. Zhou, and W Chen, 2016: Historical change and future scenarios of sea level rise in Macau and the adjacent waters. Adv. Atmos. Sci., 33, 462-475. Doi: 10.1007/s00376-015-5047-1.
14. Iman Rousta, Mohsen Soltani, W Zhou, H. N. Cheung, 2016: Analysis of Extreme Precipitation Events over Central Plateau of Iran. American Journal of Climate Change. 05, 297-313.
2015
15. Li, C. Y., and W. Zhou*, 2015: Multiscale control of summertime persistent heavy precipitation events over South China in association with synoptic, intraseasonal, and low-frequency background. Climate Dynamics, 45, 1043-1057. doi:10.1007/s00382-014-2347-6
16. Leung, Y. T., H. N. Cheung, and W. Zhou*, 2015: Energetics and dynamics associated with two typical mobile trough pathways over East Asia in boreal winter. Climate Dynamics, 44, 1611-1626. doi:10.1007/s00382-014-2355-6
17. Wang, L., W. Chen, W. Zhou, and G. Huang, 2015: Teleconnected influence of tropical Northwest Pacific Sea surface temperature on interannual variability of autumn precipitation in Southwest China. Climate Dynamics, 45, 2527-2539. doi:10.1007/s00382-015-2490-8 .
18. Qian, C., W. Zhou, S. K. Fong, and K. C. Leong, 2015: Two approaches for statistical prediction of non-Gaussian climate extremes: A case study of Macao hot extremes during 1912-2012. Journal of Climate, 28,623-636. doi:10.1175/JCLI-D-14-00159.1
19. Ye K. H., Chi-Yung Tam, Wen Zhou, and Soo-Jin Sohn, 2015: Seasonal prediction of June rainfall over South China: Model assessment and statistical downscaling. Adv. Atmos. Sci., 32, 680-689. doi:10.1007/s00376-014-4047-x.
20. Leung, Y. T., and W. Zhou*, 2015: Vertical structure, physical properties and energy exchange of the East Asian trough in boreal winter. Climate Dynamics, 45, 1635-1656. doi:10.1007/s00382-014-2419-7.
21. Leung, Y. T., and W. Zhou*, 2015: Variation of circulation and East Asian climate associated with anomalous strength and displacement of the East Asian trough. Climate Dynamics, 45, 2713-2732. doi:10.1007/s00382-015-2504-6.
22. Li, C. Y., and W. Zhou*, 2015: Interdecadal changes in summertime tropical cyclone precipitation over Southeast China during 1960-2009. Journal of Climate, 28, 1494-1509. doi:10.1175/JCLI-D-14-00246.1
23. Cheung, H. N., W. Zhou*, S. M. Lee, and H. W. Tong, 2015: Interannual and interdecadal variability of the number of cold days in Hong Kong and their relationship with large-scale circulation. Mon. Wea. Rev., 143, 1438-1454. doi 10.1175/MWR-D-14-00335.1
24. Cheung, H. N., and W. Zhou*, 2015: Implications of Ural blocking for East Asian winter climate in the CMIP5 models. Part I: Biases in the historical scenario. Journal of Climate, 28, 2203-2216. doi:10.1175/JCLI-D-14-00308.1
25. Cheung, H. N., and W. Zhou*, 2015: Implications of Ural blocking for East Asian winter climate in the CMIP5 models. Part II: Projection and uncertainty in future climate conditions. Journal of Climate, 28, 2217-2233. doi:10.1175/JCLI-D-14-00309.1
26. Xia, J. J., Z. W. Yan, W. Zhou, S. K. Fong, K. C. Leong, I. M. Tang, S. W. Chang, W. K. Leong, and S. F. Jin, 2015: Projection of the Pearl River Delta's potential submerged area due to sea level rise during the 21st century based on CMIP5 simulations. Acta Oceanologica Sinica, 34, 78-84.
27. Xia, J. J., Z. W. Yan, G. S. Jia, H. Q. Zeng, Philip Joes, W. Zhou, and A. Z. Zhang, 2015: Projections of the advance in the start of growing season during the 21st century based on CMIP5 simulations. Adv. Atmos. Sci., 32, 831-838. doi:10.1007/s00376-014-4125-0.
28. Li, XZ, W. Zhou, YQ Chen, 2015: Assessment of Regional Drought Trend and Risk over China: A Drought Climate Division Perspective. J. Climate, 18, 7025-7037. doi: 10.1175/JCLI-D-14-00403.1
29. Li. C.Y., W. Zhou, and TC. LEE, 2015: Climatological Characteristics and Observed Trends of Tropical Cyclone–Induced Rainfall and Their Influences on Long-Term Rainfall Variations in Hong Kong. Mon. Wea. Rev., 143, 2192-2206.
30. Wang, W. W., W. Zhou*, Y. Li, X. Wang, and D. Wang, 2015: Statistical modeling and CMIP5 simulations of hot spell changes in China. Clim. Dyn., 44, 2859-2872. doi:10.1007/s00382-014-2287-1
31. Wang W.W., W. Zhou*, S.K. Fong, K. C. Leung, S.W. Chang, W.K. Leung, 2015: Extreme rainfall and summer heat waves in Macao based on statistical theory of extreme values. Climate Research. 66, 91-101.
2014
32. Li, C. Y., W. Zhou*, and T. Li, 2014: Influences of the Pacific-Japan teleconnection pattern on synoptic-scale variability in the western North Pacific. Journal of Climate, 27, 140-154.
33. Wang, X., W. Zhou*, C. Y. Li, and D. X. Wang, 2014: Comparison of the impact of two types of El Niño on tropical cyclone genesis over the South China Sea. International Journal of Climatology, 34, 2651-2660, doi:10.1002/joc.3865.
34. Zhang, Z. X., M. Wenig, W. Zhou, T. Diehl, K.-L. Chan, and L. N. Wang, 2014: The contribution of different aerosol sources to the aerosol optical depth in Hong Kong. Atmospheric Environment, 83, 145-154.
35. Wang, W. W., W. Zhou*, and D. L. Chen, 2014: Summer high temperature extremes in southeast China: Bonding with the El Niño-Southern Oscillation and East Asian summer monsoon coupled system. Journal of Climate, 27, 4122-4138.
36. Li, C. Y., and W Zhou*, 2014: Interdecadal change in South China Sea tropical cyclone frequency in association with zonal sea surface temperature gradient. Journal of Climate, 27, 5468-5480.
37. Wang, Lin, W. Chen, and W. Zhou, 2014: Assessment of future drought in Southwest China based on CMIP5 multimodel projections. Adv. Atmos. Sci., 31, 1035-1050.
38. Liu, Y. Y., L. Wang, W. Zhou, and W. Chen, 2014: Three Eurasian teleconnection patterns: Spatial structures, temporal variability, and associated winter climate anomalies. Climate Dynamics, 42, 2817-2839.
39. Song, J., C. Y. Li, and W. Zhou, 2014: High and low latitude types of the downstream influences of the North Atlantic Oscillation. Climate Dynamics, 42, 1097-1111, doi:10.1007/s00382-013-1844-3.
40. Qu, X., G. Huang, and W. Zhou, 2014: Consistent responses of East Asian summer mean rainfall to global warming in CMIP5 simulations. Theoretical and Applied Climatology, 117, 123-131. doi:10.1007/s00704-013-0995-9.
41. Li, Xiuzhen, W. Zhou*, D. L. Chen, C. Y. Li, and J. Song, 2014: Water vapor transport and moisture budget over Eastern China: Remote forcing from the two types of El Niño. Journal of Climate, 27, 8778-8792.
42. Ling, J., C. Y. Li, W. Zhou, and X. L. Jia, 2014: To begin or not to begin? A case study on the MJO initiation problem. Theor. Appl. Climatol., 115, 231-241, doi:10.1007/s00704-013-0889-x.
2013
43. Li, X. Z., W. Zhou*, C. Y. Li, and J. Song, 2013: Comparison of the annual cycles of moisture supply over southwest and southeast China. Journal of Climate, 26, 10139-10158.
44. Wang, W. W., W. Zhou*, X. Wang, S. K. Fong, and K. C. Leung, 2013: Summer high temperature extremes in southeast China associated with the East Asian jet stream and circumglobal teleconnection. J. Geophys. Res., 118, 8306–8319, doi:10.1002/jgrd.50633.
45. Li, C. Y., and W. Zhou*, 2013: Modulation of Western North Pacific tropical cyclone activities by the ISO. Part 1: Genesis and intensity. Journal of Climate, 26, 2904-2918.
46. Li, C. Y., and W. Zhou*, 2013: Modulation of Western North Pacific tropical cyclone activities by the ISO. Part 2: Tracks and landfalls. Journal of Climate. 26, 2919-2930.
47. Ling, J., C. Y. Li, W. Zhou, X. L. Jia, and C. D. Zhang, 2013: Effect of boundary layer latent heating on MJO simulations. Adv. Atmos. Sci., 30, 101-115.
48. Wang, X., W. Zhou*, D. X. Wang, and C. Z. Wang, 2013: The impacts of the summer Asian jet stream biases on surface air temperature in mid-eastern China in IPCC AR4 models. Int. J. Climatol., 33, 265-276, doi:10.1002/joc.3419.
49. Cheung, H. N., W. Zhou*, H. Y. Mok, M. C. Wu, and Y. Shao, 2013: Revisiting the climatology of atmospheric blocking in the northern hemisphere. Adv. Atmos. Sci., 30, 397-410, doi:10.1007/s00376-012-2006-y.
50. Kim, J.-S., W. Zhou*, H. N. Cheung, and C. H. Chow, 2013: Variability and risk analysis of Hong Kong air-quality based on Monsoon and El Niño conditions. Adv. Atmos. Sci., 30, 280-290, doi:10.1007/s00376-012-2074-z.
51. Cheung, H. N., W. Zhou*, Y. P. Shao, W. Chen, H. Y. Mok, and M. C. Wu, 2013: Observational climatology and characteristics of wintertime atmospheric blocking over Ural-Siberia. Climate Dynamics, 41,63-79, doi:10.1007/s00382-012-1587-6.
52. Zhou, Q., W. Chen, and W. Zhou, 2013: Solar cycle modulation of the ENSO impact on the winter climate of East Asia, J. Geophys. Res. Atmos., 118, doi:10.1002/jgrd.50453.
53. Wang, X., C. Z. Wang, W. Zhou, L. Liu, and D. X. Wang, 2013: Remote influence of North Atlantic SST on the equatorial westerly wind anomalies in the western Pacific for initiating an El Niño event: An atmospheric general circulation model study. Atmospheric Science Letters, 14, 107-111, doi:10.1002/asl2.425.
54. Xiao, X. J., D. X. Wang, W. Zhou, Z. Q. Zhang, Y. H Qin., N. He, and L. L. Zeng, 2013: Impacts of a wind stress and a buoyancy flux on the seasonal variation of mixing layer depth in the South China Sea. Acta Oceanologica Sinica, 32, 30-37, doi:10.1007/s13131-013-0342-0.
2012
55. Yuan, F., W. Chen, and W. Zhou, 2012: Analysis of the role played by circulation in the persistent precipitation over South China in June 2010. Adv. Atmos. Sci., 29, 769-781.
56. Yan, Y. F., Y. Q. Qi, and W. Zhou, 2012: Variability of tropical cyclone occurrence date in the South China Sea and its relationship with SST warming. Dynamics of Atmospheres and Oceans, 55-56, 45-59.
57. Wu, Q. Z., Z. F. Wang, H. S. Chen, W. Zhou, and M. Wenig, 2012: An evaluation of air quality modeling over the Pearl River Delta during November 2006. Meteorol Atmos Phys., 116, 113-132, doi:10.1007/s00703-011-0179-z.
58. Chen, H. P., J. Q. Sun, X. L. Chen, and W. Zhou, 2012: CGCM projections of heavy rainfall events in China, Int. J. Climatol., 32, 441-450.
59. Wang, X., D. X. Wang, W. Zhou*, and C. Y. Li, 2012: Interdecadal modulation of the influence of La Niña events on Mei-yu rainfall over the Yangtze River Valley. Advances in Atmospheric Sciences, 29, 157-168, doi:10.1007/s00376-011-1021-8.
60. Wang, X., W. Zhou*, C. Y. Li, and D. X. Wang, 2012: Effects of the East Asian summer monsoon on tropical cyclone genesis over the South China Sea on interdecadal timescales. Adv. Atmos. Sci., 29, 249-262.
61. Zhou, W., W. Chen, and D. X. Wang, 2012: The implications of ENSO signal for South China monsoon climate. Aquatic Ecosystem Health & Management, 15, 14-19, doi:10.1080/14634988.2012.652050.
62. Yang, J. X., A. K. H. Lau, J. C. H. Fung, W. Zhou, and M. Wenig, 2012: An air pollution episode and its formation mechanism during the tropical cyclone Nun's landfall in a coastal city of south China. Atmospheric Environment, 54, 746-753.
63. Jiang, N. B., K. Cheung, K. Luo, P. J. Beggs, and W. Zhou, 2012: On two different objective procedures for classifying synoptic weather types over east Australia. Int. J. Climatol., 32, 1475-1494, doi:10.1002/joc.2373.
64. Cheung, H. N., W. Zhou*, H. Y. Mok, and M. C. Wu, 2012: Relationship between Ural-Siberian blocking and the East Asian winter monsoon in relation to the Arctic oscillation and the El Niño-Southern Oscillation. Journal of Climate, 25, 4242-4257, doi:10.1175/JCLI-D-11-00225.1.
65. Li, C. Y., W. Zhou*, J. C. L. Chan, and P. Huang, 2012: Asymmetric modulation of the Western North Pacific cyclogenesis by the Madden-Julian Oscillation under ENSO conditions. Journal of Climate, 25, 5374-5385, doi:10.1175/JCLI-D-11-00337.1.
66. Li, C. Y., and W. Zhou*, 2012: Changes in western Pacific tropical cyclones associated with the El Niño-Southern Oscillation cycle. Journal of Climate, 25, 5864-5878, doi:10.1175/JCLI-D-11-00430.1.
67. Li, X. Z., and W. Zhou*, 2012: Quasi-4-yr coupling between El Niño-Southern Oscillation and water vapor transport over East Asia-WNP. Journal of Climate, 25, 5879-5891, doi:10.1175/JCLI-D-11-00433.1.
68. Li, X. Z., Z. P. Wen, W. Zhou*, and D. X. Wang, 2012: Atmospheric water vapor transport associated with two decadal rainfall shifts over East China. J. Meteorol. Soc., 90, 587-602, doi:10.2151/jmsj.2012-501.
I. 主持研究项目
“Observed trends and future changes in the intensity, frequency, and duration of very hot
weather in Hong Kong” RGC General Research Fund 11306417 (GRF) (314,900.00HKD)
2018-2020
“Biases of North Atlantic Storm Track and Ural Blocking Influencing on East Asian Winter
Monsoon Projection” RGC General Research Fund 11335316 (GRF) (540,824.00HKD)
2017-2019
“ENSO Amplification on summer heat waves in South China” National Nature Science
foundation of China Grant 41675062 (710,000.00RMB), 2017-2020
“Teleconnections and Future Changes in the East Asian Winter Monsoon under Arctic
Amplification” RGC General Research Fund (GRF) 11305715 (591,152HKD), 2016-2018
“Relationship between moisture budget over East Asia-Western North Pacific and two types of NSO cycle and its decadal variation,” National Nature Science foundation of China Grant 41375096 (900,000RMB), 2014-2017
“Detection of TC induced rainfall over South China,” CityU Strategic Research Grant 7004164 (100,000HKD), 2014/9-2015/8
“Response of East Asian Monsoon and Climate to Tropical Anomalies in a GCM with Nudging,” France/HK Joint Research Scheme (FR/HKJRS) 9052010 (61,200HKD), 2013-2014
“Study on Dynamic Process of Extreme Cold Spells in South China,” CityU Strategic Research Grant 7004004 (100,000HKD), 2013/10-2014/9
“我国南方持续性干旱年代际变化与水汽输送异常”深圳市协同创新科技计划——国家和省计划配套项目(288,000RMB), 2014-2015
“Water vapor transport anomalies associated with ENSO and their impacts on water resources in the Pearl River Basin,” CityU Strategic Research Grant 7002780 (180,000HKD), 2012/5-2014/4
“Understanding hot spells and heat waves in South China in recent decades,” CityU Strategic Research Grant 7002917 (69,333HKD), 2012/12-2013/09
“The decadal variability of persistent drought over South China and its association with water vapor transport anomalies,” matching for PRC Grants (MFPRC) 9680018 (157,440HKD), 2012/1-2014/12
“Decadal variability of persistent drought in South China and its association with water vapor transport anomalies,” National Nature Science foundation of China Grant 41175079 (640,000RMB), 2012/1-2015/12
“Downscaling projection of Macao Climate Extreme,” Macao government project 9231048 (900,000HKD), 2012/9-2014/8
“Persistent drought in China after 2000,” CityU Strategic Research Grant 7002717 (174,000HKD) 2011/5-2013/4
“Characteristics of blocking events over Siberia for the present and future climate conditions, and the implications for the regional climate in South China,” RGC General Research Fund (GRF) 104410 (9041548) (582,540HKD)
“Analysis of the characteristics of blocking events over Siberia for present and future climate conditions and its implication for the regional climate over Southeast Asia,” Germany/HK joint Research Scheme (Ger/HKJRS) 9053005 (59,200HKD), 2010/1-2011/12
“A study of climatological drought over South China,” CityU Strategic Research Grant 7002505 (180,000HKD), 2009/10-2011/9
“The impacts of South China monsoon climate variability and El Niño on Hong Kong air quality” HK government ECF Grant 9211008 (249,880HKD), 2008/4-2010/4
“Study on the sea level changes in the northern South China Sea under the global warming scenario,” CityU Strategic Research Grant 7002329 (145,000HKD), 2008/4-2009/9
“The impact of NAO and ENSO-related large-scale circulation on East Asian winter monsoon,” CityU Strategic Research Grant 7002231 (180,000HKD), 2007/10-2009/9
“The impact of Pacific interdecadal signal on the winter monsoon-ENSO relationship,” Joint Project in the Knowledge Innovation Program of the Chinese Academy of Sciences (IAP 07314) (50,000RMB), 2007/9-2009/8
“Climatology of winter monsoon surges over South China,” CityU Start-up Grant 7200098 (280,000HKD), 2007/5-2008/3
“Linkage between wintertime blocking episodes over Ural Mountains and cold surge over South China,” CityU Strategic Research Grant 7002136 (180,000HKD), 2007/4-2009/3
“The interdecadal relationship between monsoon rainfall and ENSO,” Project of Key Laboratories of Tropical Marine Environmental Dynamics, South China Sea Institute of Oceanology, Chinese Academy of Sciences Grant LED0601 (20,000RMB), 2007/1-2008/12
“The Pacific interdecadal pathway and its linkage with PDO evolution,” Project of State Key Laboratory of Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics, Chinese Academy of Sciences Grant LASG2712 (20,000RMB), 2007/1-2008/12
“Interdecadal variability of East Asian monsoon and ENSO,” National Nature Science foundation of China Grant 40675051 (360,000RMB), 2007/01-2009/12
“Possible mechanism for the interdecadal variability of the East Asian monsoon,” Post-doctoral Working Foundation, Chinese Academy of Sciences Grant IAPV306 (20,000RMB), 2005/1-2006/12
II. 参与研究项目
“Drought hazards in Guangdong province: Spatio-temporal patterns, climatic drivers and societal
responses,” RGC General Research Fund (GRF) 441313, 2014/1-2015/12
“'Variability of the water and energy cycles and their impact on the extreme climate over China
under the global warming background,” 973 Basic Research Program Grant
2009CB421400, 2008/9-2013/8
“The response of South China Sea and its impact on the weather and climate over South China in
the summer season,” Joint National Natural Science Foundation of China Project
U0733002, 2008/1-2011/12
“Ocean-atmosphere interaction over the joining area of Asia and Indian-Pacific Ocean (AIPO)
and its impact on the short-term climate variation in China,” 973 Basic Research Program
Grant 2006CB403600, 2006/9-2011/8