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罗德海
——
2011-02-01 | 【 【关闭】

德海,, 1963年生,博士,研究员(二级),杰青,博士生导师      

 现主要从事大气动力学,海洋动力学和气候动力学的研究工作,在国内外刊物上发表论文数十篇,专著两部. 在国际上创造性地提出和建立了大气阻塞和北大西洋涛动(NAO)形成的行星尺度波与天气尺度波相互作用的非线性多尺度相 互作用理论模式(简称NMI模型),并在国际顶尖刊物上发表了一系列论文(Dyn. Atmos. Ocean., 2000; J. Atmos. Sci., 2005b-e,2006, 2007a-c,, 2008a-b2010a-b, 2011, 2012a-c, 2014; 2015a-c)为阻塞和NAO问题的解决开辟了一个新路。同时利用大家的理论模式可以理论上研究大西洋-欧洲阻塞分布特征和北极海冰融化导致的极寒天气。 

  获得的奖励和荣誉: 

  1996年第五届中国青年科技奖,  

  2000年第二届教育部青年教师奖. 

  2003国家杰出青年科学基金获得者 

  2005 山东省泰山学者特聘教授 

  学习和工作经历: 

  19829-19857月,成都气象学院 (现成都信息工程大学)气象系,本科学习 

  19859-19889月,天空彩票大气物理研究所,硕士研究生 

  19889-19975月,成都气象学院气象研究所,副研究员,研究员(1995年) 

  19975-200210月,中国海洋大学海洋环境学院,教授(期间获在职博士学位),博士生导师 

  200210-200310月,加拿大多伦多大学物理系,访问教授。 

  200310-200710月,中国海洋大学海洋环境学院,教授,博士生导师 

  200710-20081月,香港城市大学,访问教授 

  20081-201011月,中国海洋大学海洋环境学院,教授,博士生导师 

  20154-20155月,美国纽约州立大学Albany分校,访问教授。 

  20169-201610月,美国宾夕法尼亚州立大学,访问教授 

  201011-至今,天空彩票大气物理研究所,研究员,博士生导师 

    

  现主持的基金项目: 

     国家自然科学基金项目“北大西洋涛动与欧亚极端天气事件的发生机理, 20141-201712. 

     国家自然科学基金重点项目“全球气候变化下北半球低频模态的演变特征和机理以及与极端天气事件之间的关系, 2015-2019 

    

  主要的研究领域: 

  一.大气动力学: 

  (1)非线性多尺度相互作用理论的发展及其在阻塞和北大西洋振荡(NAO)动力学中的应用。 

  (2) 阻塞和NAO在北极海冰融化(增暖)和中纬度极端天气联系中的作用。 

  二.海洋动力学: 

  (1)大洋西边界流(黑潮延伸体和湾流)中的非线性多尺度相互作用理论。 

  (2)PDO, IPOAMO等在北极海冰融化和全球增暖停滞中的作用。 

    

  学术团体兼职: 

    

  <<中国科学-地球科学>>编委 

    

  以下国际刊物的审稿人: 

    

  <<J. Atmos. Sci.>>, <<J. Climate>>, <<Quart. J. Roy. Meteoro. Soc.>>, <<Geophys. Res. Lett.>>, << Climate Dynamics>>, <<J. Geophys. Res.>>, <<Env. Res. Lett>><<Climate Research>>, <<J. International. Climatology>>, <<Earth Science Review>>, <<Scientific Report>>等。 

    

  1999年后部分代表性国际论文(SCI):  

  (51) Chen*, X., D. Luo, S. Feldstein and S. Lee, 2017: Impact of winter Ural blocking on Arctic sea ice: Short-time variability. J. Climate (In revision).  

  (50) Luo*, B., D. Luo, L. Wu, L. Zhong and I. Simmonds, 2017: Atmospheric circulation patterns which promote winter Arctic sea ice decline, Environ. Res. Lett., 12, 054017. 

  (49) Chen* X., and D. Luo, 2017: Arctic sea ice decline and continental cold anomalies: Upstream and downstream effects of Greenland blocking. Geophys. Res. Lett., 44, doi:10.1002/2016/ GL072387. 

  (48) Gong*, T. and D. Luo, 2017: Ural blocking as an amplifier of the Arctic sea ice decline in winter. J. Climate, 30, 2639-2654 . 

  (47) Luo, D., Y. Yao, A. Dai, and I. Simmonds 2017: Increased quasi-stationarity and persistence of Ural blocking in response to Arctic warming. Part II: A theoretical explanation. J. Climate , 30, 3569-3587. 

  (46) Y. Yao*, D. Luo, A. Dai and I. Simmonds, 2017: Increased quasi-stationarity and persistence of Ural blocking and Eurasian extreme cold events in response to Arctic warming. Part I: Insight from Observational Analyses. J. Climate, 30, 3549-3568. 

  (45) D. Luo, S. Feng and L. Wu, 2016: The eddy-dipole mode interaction and the decadal variability of the Kuroshio Extension system. Ocean dynamics, 66, 1317-1332, DOI 10.1007/s10236- 016-0991-6. 

  (44) Zhong, L., L. Hua and D. Luo, 2016: The eddy-mean flow interaction and the intrusion of western boundary current into the South China Sea type basin in an idealized model. J. Phys. Ocean., 46, 2493-2527. 

  (43) D. Luo, Y. Xiao, Y. Diao, A. Dai, C. Franzke, and I. Simmonds, 2016: The impact of Ural blocking on winter warm Arctic-cold Eurasian anomalies. Part II: The link to the North Atlantic Oscillation, J. Climate, 29, 3949-3971. 

  (42) D. Luo, Y. Xiao, Y. Yao, A. Dai, I. Simmonds and C. Franzke, 2016: The impact of Ural blocking on winter warm Arctic-cold Eurasian anomalies. Part I: Blocking-induced amplification, J. Climate , 29, 3925-3947. 

  (41) Y. Yao*, D. Luo, A. Dai and S. Feldstein, 2016: The positive North Atlantic Oscillation with downstream blocking and Middle East snowstorms: Impacts of the North Atlantic jet. J. Climate, 29,1853-1876 . 

  (40) D. Luo, L. Zhong, and C. Franzke, 2015: Inverse energy cascades in an eddy-induced NAO-type flow: Scale interaction mechanism J. Atmos. Sci., 72, 3417-3448. 

  (39) D. Luo, Y. Yao, A. Dai, and S. Feldstein, 2015: The positive North Atlantic Oscillation with downstream blocking and Middle East snowstorms: The large-scale environment. J. Climate, 28, 6398-6418. 

  (38) D. Luo, Y. Yao and A. Dai, 2015: Decadal relation between European blocking and North Atlantic Oscillation during 1978-2011. Part II: A theoretical model study. J. Atmos. Sci., 72,1174-1199. 

  (37) D. Luo, Y. Yao and A. Dai, 2015: Decadal relation between European blocking and North Atlantic Oscillation during 1978-2011. Part I: Atlantic conditions. J. Atmos. Sci., 72,1152-1173 

  (36) Y. Diao*, S. Xie and D. Luo, 2015: Asymmetry of winter European surface air temperature extremes and the North Atlantic Oscillation, J. Climate, 15, 517-530. 

  (35) D. Luo, Y. Yao, and S. Feldstein, 2014: Regime transition of the North Atlantic Oscillation and extreme cold events over Europe in January-February 2011/12. Mon. Wea. Rev., 142, 4735-4757. 

  (34) D. Luo, J. Cha, L. Zhong and A. Dai, 2014: A nonlinear multi-scale interaction model for atmospheric blocking: The eddy-blocking matching mechanism. Quart. J. Roy. Meteo. Soc., 140,1785–1808, July 2014 B DOI:10.1002/qj.2337. 

  (33) D. Luo and S. Ren, 2014: Impact of the SST-wind stress coupling on the dynamics and stability of ocean current inside and outside SST frontal zones, Dyn. Atmos. Oceans, 67, 47-64. 

  (32) T. Gong*, S. Feldstein and D. Luo, 2013: A simple GCM model study on the relationship between ENSO and the Southern Annular Mode. J. Atmos. Sci., 75, 1821-1832. 

  (31) Jiang, Z., M. Mu and D. Luo, 2013: A study of the North Atlantic Oscillation using         conditional nonlinear optimal perturbation. J. Atmos. Sci., 70, 855-875. 

  (30) D. Luo, and J. Cha, 2012: The North Atlantic Oscillation and North Atlantic jet variability: Precursors to NAO regimes and transitions. J. Atmos. Sci., 69, 3763-3787. 

    

  (29) D. Luo, J. Cha and S. Feldstein, 2012b: Weather regime transitions and the interannual variability of the North Atlantic Oscillation. Part II: Dynamical processes. J. Atmos. Sci., 69, 2347-2363. 

  (28) D. Luo, J. Cha and S. Feldstein, 2012a: Weather regime transitions and the interannual variability of the North Atlantic Oscillation. Part I: A likely connection. J. Atmos. Sci., 69, 2329-2346 

  (27) D. Luo, Y. Diao and S. B. Feldstein, 2011:  The variability of the Atlantic storm track activity and North Atlantic Oscillations: A link between intraseasonal and interannual variability, J. Atmos. Sci., 68, 577-601. 

  (26) D. Luo, L. Zhong, R. Ren and C. Wang, 2010b: Spatial pattern and zonal shift of the North Atlantic Oscillation. Part II: Numerical experiments. J. Atmos. Sci., 67, 2827-2853 

  (25) D. Luo, Z. Zhu, R. Ren, L. Zhong and C. Wang, 2010a: Spatial pattern and zonal shift of the North Atlantic Oscillation. Part I: A dynamical interpretation. J. Atmos. Sci., 67, 2805-2826. 

  (24), T. Gong*, S. B. Feldstein and D. Luo, 2010: The impact of ENSO on wave breaking and Southern annular mode events. J. Atmos. Sci., 67, 2854-2870 

  (23) D. Luo, W. Zhou, and K. Wei, 2010: Dynamics of eddy-driven North Atlantic Oscillations in a localized shifting jet: zonal structure and downstream blocking, Climate dynamics,34, 73-100. DOI 10.1007/s00382-009-0559-y. 

  (22) Y., Wang*, S. Li, and D. Luo, 2009, Seasonal response of Asian monsoonal climate to the Atlantic Multidecadal Oscillation, J. Geophys. Res., 114, D02112, doi:10.1029/2008JD010929 

  (21) D. Luo, T. Gong and L. Zhong, 2008b: Dynamical relationship between the phase of North Atlantic Oscillations and meridional excursion of a preexisting jet: An analytical study. J. Atmos. Sci., 65, 1838-1858 

  (20)D. Luo, T. Gong and Y. Diao, 2008a: Dynamics of eddy-driven low-frequency dipole modes. Part IV: Planetary and synoptic wave breaking processes during the NAO life cycle. J. Atmos. Sci., 65, 737-765. 

  (19) D. Luo, T. Gong , Y. Diao and W. Zhou, 2007: Storm tracks and Annular Modes. Geophys. Res. Lett.., 34, L1780110.1029/2007GL030436. 

  (18) D. Luo, T. Gong and Y. Diao, 2007c: Dynamics of eddy-driven low-frequency dipole modes. Part III: Meridional shifts of westerly jet anomalies during two phases of NAO. J. Atmos. Sci. 643232-3243. 

  (17)D. Luo, T. Gong and A., R. Lupo, 2007b: Dynamics of eddy-driven low- frequency dipole modes. Part II: Free mode characteristics of NAO and diagnostic study. J. Atmos. Sci., 64, 29-51. 

  (16)D. Luo, A., R. Lupo and H. Wan, 2007a: Dynamics of eddy-driven low-frequency dipole modes. Part I: A simple model of North Atlantic Oscillations. J. Atmos. Sci., 64, 3-28. 

  (15) D. Luo and T. Gong, 2006c: A possible mechanism for the eastward shift of interannual NAO action centers in last three decades. Geophy. Res. Lett., 33, L24815, doi:10.1029 /2006G L027860. 

  (14)D. Luo and Z. Chen, 2006b: The role of land-sea topography in blocking formation in a block-eddy interaction model, J. Atmos. Sci.633056-3065. 

  (13) Y. Diao*, J. Li and D. Luo, 2006a: A new blocking index and its application: Blocking action in the Northern Hemisphere, J. Climate, 19, 4819-4839. 

  (12) D. Luo and H. Wan, 2005g: Decadal variability of wintertime North Atlantic and Pacific blockings: A possible cause, Geophys. Res. Lett., 32, L23810, doi: 10. 1029/2005GL024329. 

  (11) D. Luo, 2005f: Why is the North Atlantic block more frequent and long-lived during the negative NAO phase, Geophys. Res. Lett., 32, L20804,doi:10, 1029/ 2005GL022927. 

  (10) D. Luo, 2005e: A barotropic envelope Rossby soliton model for block-eddy interaction. Part IV: Block activity and its linkage with sheared environment, J. Atmos. Sci. 62, 3860-3884 

  (9) D. Luo, 2005d: A barotropic envelope Rossby soliton model for block-eddy interaction. Part III: Wavenumber conservation theorems for isolated blocks and deformed eddies, J. Atmos. Sci., 62, 3839-3859 

  (8) D. Luo, 2005c: A barotropic envelope Rossby soliton model for block-eddy interaction. Part II: Role of westward-traveling planetary waves, J. Atmos. Sci., 62, 22-40.  

  (7) D. Luo, 2005b: A barotropic envelope Rossby soliton model for block-eddy interaction. Part I: Effect of topography, J. Atmos. Sci., 62,5-21. 

  (6) D. Luo, 2005a: Interaction between envelope soliton vortex pair block and synoptic-scale eddies in an inhomogeneous baroclinicity environment, Quart. J. Roy. Meteoro. Soc. ,131, 125-154. 

  (5) D. Luo, Huang F. and Y. Diao, 2001: Interaction between antecedent planetary- scale envelope soliton blocking anticyclone and synoptic-scale eddies: Observations and theory. J. Geophys. Res. Vol. 106, 31795—31816. 

  (4) D. Luo, 2001: Derivation of a higher order nonlinear Schr?dinger equation for weakly nonlinear Rossby waves, Wave Motion, 33,339-347.. 

  (3) D. Luo and Y. Lu, 2000: The influence of negative viscosity on wind-driven ocean circulation in a subtropical basin, J. Phys. Ocean., 30, 916-932 . 

  (2) D. Luo, 2000: Planetary-scale baroclinic envelope Rossby solitons in a two- layer model and their interaction with synoptic-scale eddies. Dyn. Atmos. Oceans, 32, 27-74. 

  (1) D. Luo, 1999, Near-resonantly topographically forced envelope Rossby solitons in a barotropic flow. Geophys. Astrophys. Fluid Dyn., 90, 161-188. 

    

  :凡是本人为第一编辑的论文,均为第一编辑执笔完成。*为学生。 

    

  欢迎有志于从事气候动力学和气候变化(大气科学和海洋科学)并具有很高数理基础的青年学生加入大家的研究团队. 我办公室的电话: 010-82995213(北京)Email:ldh@mail.iap.ac.cn 

    

  20176月更新 

 

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