河海大学海洋学院导师教师师资介绍简介-王召民

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王召民，男，教授，研究生学历，博士学位
电子邮箱:zhaomin.wang@hhu.edu.cn
工作电话：

个人简历
教育背景
1999年6月-2001年7月：加拿大麦吉尔大学大气与海洋科学系，博士后（导师L. A. MYSAK教授）；
1995年9月-1999年6月：加拿大麦吉尔大学大气与海洋科学系，博士学位（导师L. A. MYSAK教授）；
1984年9月-1987年7月：南京大学大气科学系，硕士学位（导师黄士松教授）；
1980年9月-1984年7月：南京大学大气科学学院，学士学位。
工作经历
2017年1月至今：河海大学海洋学院，教授；
2012年1月-2016年12月：南京信息工程大学，教授；
2006年1月-2011年12月：英国南极局，终身研究员；
2001年8月-2005年12月：加拿大麦吉尔大学大气与海洋科学系，副研究员；
1999年8月-2001年7月：加拿大麦吉尔大学大气与海洋科学系，博士后；
1987年8月-1995年8月：南京大学大气科学学院，讲师。

研究兴趣
海洋环流与全球气候变化；
极地气候系统,大气-海洋-海冰-冰架-冰盖相互作用；
海洋环流高分辨率数值模拟；
气候模式发展与气候模拟；
南极陆架海动力过程。

研究基金
1.国家自然科学基金面上项目(**)：南极涛动对大西洋经向翻转环流的影响研究，2013年1月至2016年12月，主持，84万元。
2.国家科技部973项目(2010CB950301)：南大洋大气-海洋-冰相互作用研究，2012年6月至2014年12月，参加。
3. 国家气象局行业专项(GYHY)：气候系统模式关键物理过程不确定性对东亚气候的影响研究，2013年1月至2016年12月，主持第三课题“大气海洋过程及其对东亚季风的影响”，67万元。
4. 国家科技部973项目(2015CB953900)：北极海冰减退引起的北极放大机理与全球气候效应，2015年1月至2019年12月，第四课题(2015CB953904）负责人：北极放大的全球效应及对中国气候的影响机理，566万元。
5. 国家科技部国家重点研发计划项目(2016YFA**)：全球变暖“停滞”现象辨识与机理研究，第四课题全球变暖停滞模拟与预估及区域气候响应，2016年7月至2021年6月，92万元。
6. 国家自然科学基金面上项目(**)：冰晶过程对冰架底部融化冻结的影响研究，2019年1月至2022年12月，主持，65万元。
7. 国家自然科学基金极地专项重点项目(**)：多尺度海洋环流与埃默里冰架底部质量平衡的相互作用研究，2020年1月至2023年12月，主持，305万元。
8. 国家海洋局极地考察办公室创新平台项目(CXPT**)：风暴与海冰快速减少关系分析，2020年7月至2021年7月，主持，25万元。

论文论著
1. Cheng, C. and A. Jenkins, Wang Z., LiuC. (2020) Modeling the vertical structure of the ice shelf–ocean boundary current under supercooled condition with suspended frazil ice processes: A case study underneath the Amery Ice Shelf, East Antarctica. Ocean Modelling, 156: 101712.
2. 张向东,傅云飞,管兆勇,唐汉,王国民,王召民,武培立,杨修群.北极增幅性变暖对欧亚大陆冬季极端天气和气候的影响:共识、问题和争议[J].气象科学, 2020, 40(05): 596-604.
3. 杨修群,王国民,张向东,王召民,管兆勇.大气环流与灾害性天气气候研究:黄士松先生学术成就和贡献回顾[J].气象科学, 2020, 40(05): 569-584.
4. 钱江潮,王召民*,刘成彦,李丙瑞. 1972—2019年南极威德尔冰间湖以及莫德高地冰间湖的特征分析[J].气象科学, 2020, 40(05): 721-732.
5. 田霏,王召民*, Gavilan Estanislao,刘成彦*.北极河流径流对北冰洋环流的影响[J].海洋学报, 2020, 42(07): 1-15.
6. Turner J., Guarino M. V., Arnatt J., Jena B., Marshall G. J., Phillips T., Bajish C. C., Clem K.,Wang Z., Andersson T., Murphy E. J., Cavanagh R. (2020) Recentdecreaseofsummersea ice in the Weddell Sea, Antarctica.Geophysical Research Letters, 47, e2020GL087127. https://doi.org/10.1029/2020GL087127
7. Wu, Y., Wang, Z.*, Liu, C., & Lin, X. (2020) Impacts of High-Frequency Atmospheric Forcing on the Southern Ocean Circulation and Antarctic Sea Ice, Adv. Atmos. Sci., DOI: 10.1007/s00376-020-9203-x
8.Lin, X., Zhai, X.*,Wang, Z.*, & Munday, D. R. (2020) Southern Ocean wind stress in CMIP5 models: Role of wind fluctuations. Journal of Climate, 33(4), 1209-1226.
9. 谢泽林,王召民*,武扬.风应力输入到海洋中的能量的气候变率特征[J].大气科学学报, 2019, 42(02): 184-196.
10. Zhaomin Wang*, John Turner, Yang Wu, Chengyan Liu.(2019) Rapid decline of total Antarctic sea ice extent during 2014 – 2016 controlled by wind-driven sea ice drift, Journal of Climate, DOI: 10.1175/JCLI-D-18-0635.1.
11. Zhaomin Wang*and Dake Chen. Polar climate system modeling in China: Recent progress and future challenges, Sci. China Earth Sci. (2019)62: 1076. https://doi.org/10.1007/s11430-018-9355-2.
12. Cheng, C., Jenkins, A., Holland, P. R., Wang, Z.*, Liu, C., & Xia, R. (2019) Responses of sub-ice platelet layer thickening rate and frazil-ice concentration to variations in ice-shelf water supercooling in McMurdo Sound, Antarctica. The Cryosphere, 13(1), 265-280.
13. Wei, J., Zhang, X.*&Wang, Z.*Reexamination of Fram Strait sea ice export and its role in recently accelerated Arctic sea ice retreat. ClimDyn(2019) 53: 1823. https://doi.org/10.1007/s00382-019-04741-0
14. YanLiangjun,Wang Zhaomin*, LiuChengyan, Wu Yang. On the determination and simulation of seawater freezing point temperature under high pressure. Advances in Polar Science, 2019, 30(04): 391-398.
15. Turner, J., Phillips, T., Thamban, M.,Rahaman, W., Marshall, G. J.,Wille, J. D., FavierV., Winton V. H. L., Thomas E.,Wang Z., Broeke M. van den, Hosking J. S., Lachlan-Cope T. (2019). The dominantrole of extreme precipitation events inAntarctic snowfall variability.Geophysical Research Letters, 46,3502–3511. https://doi.org/10.1029/2018GL081517
16. Basu S, Zhang X, Wang Z.A Modeling Investigation of Northern Hemisphere Extratropical Cyclone Activity in Spring: The Linkage between Extreme Weather and Arctic Sea Ice Forcing. Climate. 2019, 7(2):25.
17. Liu C, Wang Z*, Cheng C, et al. On the modified Circumpolar Deep Water upwelling over the Four Ladies Bank in Prydz Bay, East Antarctica[J]. Journal of Geophysical Research: Oceans, 2018.
18.Wei,J.,Zhang,X.*,&Wang,Z.*(2018).ImpactsofextratropicalstormtracksonArcticseaice export throughFramStrait.ClimateDynamics,1-12.
19. Lin. X., X. Zhai*, Z. Wang, and D. Munday, Mean, variability and trend of Southern Ocean wind stress: Role of wind fluctuations, J. Climate, 2018(31), 3557–3573.
20. Xia Lin, Zhaomin Wang. Simulated impact of Southern Hemisphere westerlies on Antarctic Continental Shelf Bottom Water temperature.Advances in Polar Science, 2018, 29(03): 215-221.
21. Zhaomin Wang, Xiangdong Zhang, John Turner, Annette Rinke. Workshop on Polar Climate Changes and Extreme Events. Advances in Polar Science, 2018, 29(03): 151-155.
22. 谢泽林,王召民*.普里兹湾区域风和温度资料对比分析:以2007年为例[J].极地研究, 2017, 29(03): 368-377.
23. SoumikBasu, Xiangdong Zhang*, Zhaomin Wang*, Eurasian Winter Storm Activity at the End of the Century: A CMIP5 Multi-model Ensemble Projection, Earth’s Future, 2017, DOI: 10.1002/2017EF000670
24. Chen Cheng, Zhaomin Wang*, Chengyan Liu, and Ruibin Xia, Vertical modification ondepth-integrated ice shelf water plume modelingbased on an equilibrium vertical profile of suspended frazil ice concentration, Journal of Physical Oceanography, 2017, doi:10.1175/JPO-D-17-0092.1
25. Liu, C., Z. Wang*, C. Cheng, R. Xia, B. Li, and Z. Xie (2017), Modeling modified Circumpolar Deep Water intrusions onto the Prydz Bay continental shelf, East Antarctica, J. Geophys. Res. Oceans, 122, 5198–5217, doi:10.1002/2016JC012336.
26. Yang Wu, Xiaoming Zhai*, Zhaomin Wang*, Decadal-mean impact of including ocean surface currents in bulk formula on surface air-sea fluxes and ocean general circulation. J. Climate, 2017, doi:10.1175/JCLI-D-17-0001.
27. Wu, Y., Z. Wang*, and C. Liu (2017), On the response of the Lorenz energy cycle for the Southern Ocean to intensified westerlies, Journal of Geophysical Research: Oceans, 122, doi:10.1002/2016JC012539.
28. Liu, C. Y., Z. M. Wang, B. R. Li, C. Cheng, and R. B. Xia, 2017: On the response of subduction in the SouthPacific to an intensification of westerlies and heat flux in an eddy permitting ocean model. Adv. Atmos. Sci., 34(4), 521–531, doi: 10.1007/s00376-016-6021-2.
29. Zhaomin Wang*, Yang Wu, Xia Lin, Chengyan Liu, ZelinXie, Impacts of open-ocean deep convection in the Weddell Sea on coastal and bottom water temperature, Climate Dynamics, 2017, doi:10.1007/s00382-016-3244-y
30. 林霞,王召民*.最近21年厄加勒斯反曲的变化[J].中国海洋大学学报(自然科学版), 2016, 46(07): 11-14.
31. Yang Wu, XiaomingZhai, Zhaomin Wang. Impact of Synoptic Atmospheric Forcing on the Mean Ocean Circulation, Journal of Climate, 2016, DOI: http://dx.doi.org/10.1175/JCLI-D-15-0819.1.
32. 丁明虎,卞林根,张林,王召民,逯昌贵,孙维君,袁乃明,傅良,谢泽林.中国南极维多利亚地新站气象特征分析[J].极地研究, 2015, 27(04): 344-350.
33. 谢涛,方贺,赵尚卓,于文金,王召民,何宜军.基于合成孔径雷达遥感的北极海冰总形变率分析[J].海洋学报, 2015, 37(11): 118-126.
34. ZhaoJ., ShiJ., Wang Z., LiZ., & HuangF. (2015). Arctic amplification produced by sea ice retreat and its global climate effects. Advances in Earth Science, 30(9), 985-995.
35. Zhaomin Wang*, Xiangdong Zhang, Zhaoyong Guan, Bo Sun, Xin Yang &Chengyan Liu,An atmospheric origin of the multi-decadal bipolar seesaw. Scientific Reports 5, 8909; DOI:10.1038/srep08909 (2015).
36. Ye Wang, Xiaodong Yan, Zhaomin Wang. A preliminary study to investigate the biogeophysical impact of desertification on climate based on different latitudinal bands. International Journal of Climatology, Article first published online: 12 JUN 2015，DOI:10.1002/joc.4396，2015.
37. Ye Wang,Zhaomin Wang.(2015). Contribution of surface roughness to simulations of historical deforestation. Physics and Chemistry of the Earth, Parts A/B/C 87-88: 119-125.
38. 朱芳泽,王召民*,刘成彦,黄河清,詹德权,葛琛琦,林霞,谢泽林. BCC_CSM对全球海表温度和混合层深度的模拟评估[J].大气科学学报, 2014, 37(06): 684-694.
39.Zhaomin Wang*, John Turner, Bo Sun, Bingrui Li &Chengyan Liu （2014），Cyclone-induced rapid creation of extreme Antarctic sea ice conditions，Scientific Reports4, 5317；doi:10.1038/srep05317
40. Ye Wang, Xiaodong Yan, Zhaomin Wang. The biogeophysical effects of extreme afforestation in modeling future climate. Theoretical and Applied Climatology, 118, 511–521,doi: 10.1007/s00704-013-1085-8, 2014.
41. Ye Wang, Xiaodong Yan, Zhaomin Wang. Global warming caused by afforestation in the Southern Hemisphere. Ecological Indicators, doi: 10.1016/j.ecolind.2014.12.004, 2014.
42. Ye Wang, Xiaodong Yan, Zhaomin Wang. Effects of regional afforestation on global climate. Journal of Water and Climate Change, doi: 10.2166/wcc.2014.136, 2014.
43. Liu, Chengyan and Zhaomin Wang(2014), On the response of the Global Subduction Rate to global warming in coupled climate models, Advance in Atmospheric Sciences 31(1)，211-218.
44. Ye Wang, Xiaodong Yan, Zhaomin Wang.Simulation of the influence of historical land cover changes on the global climate. Annales Geophysicae, 31, 995-1004, 2013.
45. Sallée, J.-B., E. Shuckburgh, N. Bruneau, A. J. S. Meijers, T. J. Bracegirdle, Z. Wang, and T. Roy(2013), Assessment of Southern Ocean water mass circulation and characteristics in CMIP5 models: Historical bias and forcing response, J. Geophys. Res. Oceans, 118, doi:10.1002/jgrc.20135.
46. Sallée, J.-B., E. Shuckburgh, N. Bruneau, A. J. S. Meijers, T. J. Bracegirdle, and Z. Wang(2013), Assessment of Southern Ocean mixed layer depths in CMIP5 models: Historical bias and forcing response, J. Geophys. Res. Oceans, 118, doi:10.1002/jgrc.20157
47. Wang, Z.(2013), On the response of Southern Hemisphere subpolar gyres to climate change in coupled climate models, J. Geophys. Res. Oceans, 118, 1070–1086, doi:10.1002/jgrc.20111.
48. Bracegirdle, T. J., E. Shuckburgh, J.-B. Sallee,Z. Wang,A. J. S. Meijers, N. Bruneau, T. Phillips, and L. J. Wilcox(2013), Assessment of surface winds over the Atlantic, Indian, and Pacific Ocean sectors of the Southern Ocean in CMIP5 models: historical bias, forcing response, and state dependence, J. Geophys. Res. Atmos., 118, 547–562, doi:10.1002/jgrd.50153
49. Meijers, A. J. S., E. Shuckburgh, N. Bruneau, J.-B. Sallee, T. J. Bracegirdle, and Z. Wang(2012), Representation of the Antarctic Circumpolar Current in the CMIP5 climate models and future changes under warming scenarios, J. Geophys. Res., 117, C12008, doi:10.1029/2012JC008412.
50. T.Kuhlbrodt, R.S. Smith, Z. Wang, and J.M. Gregory，The influence of eddy parameterizations on the transport of the Antarctic Circumpolar Current in coupled climate models，Ocean Modelling, Vol.52-53,1-8, 2012
51. 马浩,王召民,史久新.南大洋物理过程在全球气候系统中的作用[J].地球科学进展, 2012, 27(04): 398-412.
52. Julian Gutt, Damaris Zurell, Thomas J. Bracegridle, William Cheung, Melody S. Clark, Peter Convey, Bruno Danis, Bruno David, Claude De Broyer, Guido di Prisco, Huw Griffiths, RémiLaffont, Lloyd Peck, Benjamin Pierrat, Martin J. Riddle,ThomasSaucede, John Turner, Cinzia Verde, Zhaomin Wang, Volker Grimm, The use of correlative and dynamic species distribution modelling for ecological predictions in the Antarctic: a cross-disciplinary concept, Polar Research,2012, 31, 11091, http://dx.doi.org/10.3402/polar.v31i0.11091
53. Wang, Z.*, T. Kuhlbrodt and M. P. Meredith, On the response of the Antarctic Circumpolar Current transport to climate change in coupled climate models, Journal of Geophysical Research, VOL. 116, C08011, 17 PP., 2011 doi:10.1029/2010JC006757
54. Graham, J. A., D. P. Stevens, K. J. Heywood, andZ. Wang, North Atlantic climate responses to perturbations in Antarctic Intermediate Water, Clim. Dyn., 2011, Volume 37, Numbers 1-2, Pages 297-311.
55. Wang, Z., (contributed to) Antarctic Climate Change and the Environment (http://www.scar.org/publications/occasionals/acce.html), Edited by Turner, J., Bindschadler, R.A., Convey, P., Di Prisco, G., Fahrbach, E., Gutt, J., Hodgson, D.A., Mayewski, P.A., and Summerhayes, C.P., Published in Cambridge by SCAR, ISBN 978-0-948277-22-1
56. Philip C. Reid, Astrid C. Fischer, Emily Lewis-Brown, Michael P. Meredith, Mike Sparrow, Andreas J. Andersson, AvanAntia, Nicholas R. Bates, Ulrich Bathmann, Gregory Beaugrand, Holger Brix, Stephen Dye, Martin Edwards, Tore Furevik, ReidunGangst?, HjálmarHátún, Russell R. Hopcroft, Mike Kendall, Sabine Kasten, Ralph Keeling, Corinne Le Quéré, Fred T. Mackenzie, Gill Malin, CecilieMauritzen, Jón ólafsson, Charlie Paull, Eric Rignot, Koji Shimada, Meike Vogt, Craig Wallace, Zhaomin Wang, and Richard Washington, Impacts of the Oceans on Climate Change. Advances in Marine Biology, Vol. 56, 2009, pp. 1-150.
57. Turner J., J. C. Comiso, G. J. Marshall, T. A. Lachlan-Cope, T. Bracegirdle, T. Maksym, M. P. Meredith,Z. Wang, A. Orr (2009), Non-annular atmospheric circulation change induced by stratospheric ozone depletion and its role in the recent increase of Antarctic sea ice extent, Geophys. Res. Lett., 36, L08502, doi:10.1029/2009GL037524.
58. Wang, Z.*and M. P. Meredith, 2008: Density-driven Southern Hemisphere subpolar gyres in coupled climate models, Geophysical Research Letters, 35, L14608, doi: 10.1029/2008GL034344.
59. Shi, ZhengGuo, XiaoDong Yan, ChongHua Yin and ZhaoMin Wang, 2007: Effects of historical land cover changes on climate, Chinese Science Bulletin, 52(18):2575-2583.
60. Yin, ChongHua, XiaoDong Yan, ZhengGuo Shi and ZhaoMin Wang, 2007: Simulation of the climatic effects of natural forcings during the pre-industrial era, Chinese Science Bulletin, 52(11):1545-1558.
61. Zhaomin Wang, 2007: Atlantic thermohaline circulation and abrupt climate changes, Advances in Climate Change Research, 3(1): 1-7.
62. Cochelin, A.-S. B., L. A. Mysak and Z. Wang, 2006: Simulation of long-term future climate changes with the Green McGill Paleoclimate Model: The next glacial inception. Climatic Change, 79:381-401, DOI 10.1007/s10584-006-9099-1.
63. Wang, Z.*and L.A. Mysak, 2006: Glacial abrupt climate changes and Dansgaard-Oeschger oscillations in a coupled climate model. Paleoceanography, 21, PA2001, doi:10.1029/2005PA001238, 2006.
64. Papa, B., L. A. Mysak andZ. Wang*, 2006: Intermittent ice sheet discharge events in northeastern North America during the last glacial period. Climate Dynamics, 26: 201-216, DOI: 10.1007/s00382-005-0078-4.
65. Rahmstorf, S., M. Crucifix, A. Ganopolski, H. Goosse, I. Kamenkovich, R. Knutti, G. Lohmann, B. Marsh, L.A. Mysak, Z. Wang, and A. Weaver, 2005: Thermohaline circulation hysteresis: a model intercomparison. Geophysical Research Letters, 32, L23605, DOI: 10.1029/2005GL023655.
66. Petoukhov, V., M. Claussen, A. Berger, M. Crucifix, M. Eby, A. Eliseev, T. Fichefet, A. Ganopolski, H. Goosse, I. Kamenkovich, I. Mokhov, M. Montoya, L. A. Mysak, A. Sokolov, P. Stone, Z. Wangand A. Weaver, 2005: EMIC intercomparison project (EMIP - CO2): Comparative analysis of EMIC simulations of current climate and equilibrium and transient responses to atmospheric CO2 doubling. Climate Dynamics, 25: 363-385, doi: 10.1007/s00382-005-0042-3.
67. Wang, Z.*, 2005: Two climatic states and feedbacks on thermohaline circulation in an Earth System Model of Intermediate Complexity. Climate Dynamics, 25: 299-314, doi: 10.1007/s00382-005-0033-4.
68. Wang, Z.*, A.-S. B. Cochelin, L. A. Mysak and Y. Wang, 2005: Simulation of the Last Glacial Inception with the Green McGill Paleoclimate Model. Geophys. Res. Lett., 32, L12705, doi:10.1029/2005GL023047.
69. Wang, Y., L.A. Mysak, Z. Wangand V. Brovkin, 2005: The greening of the McGill Paleoclimate Model. Part II. Simulation of natural millennial-scale variability during the Holocene. Climate Dynamics, 24: 481-496.
70. Wang, Y., L.A. Mysak,Z. Wangand V. Brovkin, 2005: The greening of the McGill Paleoclimate Model. Part I: Improved land surface scheme with vegetation dynamics. Climate Dynamics, 24: 469-480.
71. Wang, Z.*, R.-M. Hu and L.A. Mysak, 2004: Reply to the comment (on 16) by A.J. Weaver and M. Eby. Atmosphere-Ocean, 42(4):295-296.
72. Wang, Z.*, R.-M. Hu, L.A. Mysak, J.-P. Blanchet and J. Feng, 2004: A parameterization of solar energy disposition in the climate system. Atmosphere-Ocean, 42: 113-125.
73. Wang, Z.* and L. A. Mysak, 2002: Simulation of the Last Glacial Inception and Rapid Ice Sheet Growth in the McGill Paleoclimate Model, Geophys. Res. Lett., 29(23), 2102, doi: 10.1029/2002GL015120.
74. Smith, G, L. A. Mysak, Z. Wangand H. Blatter, 2002: McGill paleoclimate model ice sheet sensitivity to ice flow rate and discharge parameters. Climate Dynamics, 20, 315-325, doi: 10.1007/s00382-002-0273-5.
75. Wang, Z.*, L. A. Mysak and J. F. McManus, 2002: Response of the thermohaline circulation to cold climates, Paleoceanography, 17(1), 10.1029/2000PA00587.
76. Claussen, M., L. A. Mysak, A. J. Weaver, M. Crucifix, T. Fichefet, M.-F. Loutre, S. L. Weber, J. Alcamo, V. A. Alexeev, A. Berger, R. Calov, A. Ganopolski, H. Goose, G. Lohmann, F. Lunkeit, I. I. Mokhov, V. Petoukov, P. Stone andZ. Wang, 2002: Earth system models of intermediate complexity: Closing the gapin the spectrum of climate system models. Climate Dynamics, 18, 579-586.
77. S. C. Newbigging, L. A. Mysak and Z. Wang, 2001: A stabilizing atmospheric feedback on the ocean thermohaline circulation, The Global Atmosphere-Ocean System, 7, 347-364.
78. Wang, Z.*and L. A. Mysak, 2001: Ice sheet-thermohaline circulation interactions in a climate model of intermediate complexity. Journal of Oceanography, 57, 481-494.
79. Mysak, L. A. and Zhaomin Wang, 2000: The McGill Paleoclimate Model (MPM): A New Earth System Model of Intermediate Complexity, Canadian Meteorological and Oceanographic Society Bulletin, 28, 104-109.
80.Wang, Z.*and L. A. Mysak, 2000: Are there interannual-to-decadal scale oscillations associated with sea ice-thermohaline circulation interactions in a simple coupled atmosphere-ocean-sea ice model?. Scientia MeteorologicaSinica (in China), 20, 413-426.
81.Wang, Z.*and L. A. Mysak, 2000: A simple coupled atmosphere-ocean-sea ice-land surface model for climate and paleoclimate studies. J. Climate, 13, 1150-1172.
82. Wang, Z. and S. Huang, 1996: Temporal-spatial characteristics of Antarctic and Arctic sea ice variability (In Chinese). Scientia MeteorologicaSinica, 16(4), 299-307.
83. Wang, G. and Z. Wang, 1996: Identification of persistent modes of anomalies and their impact on predictability in the barotropic atmosphere with orographic forcing (In Chinese). Chinese Journal of Atmosphere Sciences, 20, 207-215.
84. 黄士松,杨修群,蒋全荣,汤明敏,王召民,谢倩,朱永春.极地海冰变化对气候的影响[J].气象科学, 1995(04): 46-56.
85. Wang, Z. and S. Huang, 1994: The responses of global atmosphere circulation to the anomalies of Antarctic sea ice in July (In Chinese). Scientia MeteorologicaSinica, 14(4), 311-321.
86. Wang, Z., Y. Ni and Q. Zhang, 1993: The mechanism of the intraseasonaloscillations in the observational atmosphere (In Chinese). Scientia MeteorologicaSinica, 13(3), 282-288.
87. 张勤,倪允琪,林武银, 王召民, D.D.Houghton.热带和中高纬地区季节内振荡的特征及其动力学诊断[J].热带气象, 1992(04): 289-296.
88.Wang, Z., Y. Ni and Q. Zhang, 1992: Diagnostic study for intraseasonal oscillations of the middle-high latitudes in the observational atmosphere (In Chinese). Scientia MeteorologicaSinica, 12(3), 266-276.
89.Zhang, Q., Y. Ni, W. Lin and Z. Wang. 1991: Diagnostic study for intraseasonal oscillations of the middle-high latitudes in a low resolution global spectral model (In Chinese). Acta MeteorologicaSinica, 5(4), 411-425.
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表彰奖励
1. Hidaka奖,2003,日本海洋学会；
2. Tertia M.C. Hughes纪念奖(最佳博士论文奖),2000,加拿大气象与海洋学会；
3.麦吉尔大学Max Dunbar海洋奖,2000,加拿大麦吉尔大学；
4.麦吉尔大学Dean’s Honour List(杰出博士研究生奖),1999,加拿大麦吉尔大学；
5.麦吉尔大学Major Fellowship,1998-1999,加拿大麦吉尔大学；
6. 魁北克省Fonds pour la formation des chercheurs et l’aide à la recherche Fellowship,1998,加拿大魁北克；
7. 麦吉尔大学Major Fellowship,1997-1998,加拿大麦吉尔大学；
8. 麦吉尔大学北京纪念奖,1997-1998,加拿大麦吉尔大学；
9. 南京大学杰出研究生奖,1987,南京大学。

学术兼职
国际南极气候与环境变化专家组成员；
加拿大Atmosphere-Ocean编委；
德国、瑞士、比利时等国科学基金会特聘国际评审专家；
Nature出版集团Scientific Reports的Editorial Board Member；
国际南极研究科学委员会（Scientific Committeeon Antarctic Research,SCAR）中国代表（物理学）；
国家自然科学基金委共享航次第三次专家组成员，2018-2020；
国际南大洋观测组织罗斯海区域专家组成员；
IUGG国际气候委员（International Commission on Climate）会执行委员；
SCAR科学研究计划气候系统变率和预测（Near-term Variability and Prediction of the Antarctic Climate System）科学指导委员会成员。
External reviewer of the book 'The Climate of Past Interglacials';
External reviewer of Chinese Polar Research Program2011;
Expert reviewer of IPCC Fifth Assessment Report Climate Change 2013: The Physical Science Basis.