OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

中国科学地球科学中国科学地球科学 2012

区域海气耦合模式研究进展

, PP. 1301-1316

彭世球,刘段灵,孙照渤,李毅能

Keywords: 区域海气耦合模式,耦合器,侧边界条件,资料同化,动力降尺度

Full-Text Cite this paper Add to My Lib

Abstract:

？本文扼要回顾了海气耦合模式的发展历程,然后介绍了国内外区域海气耦合模式的研究现状与最新进展,并对发展区域海气耦合模式所涉及的一些核心技术和科学问题进行论述,其中包括耦合技术、侧边界处理、海气与海浪(海冰)的耦合和资料同化等问题.另外,文中还讨论了区域海气耦合模式在数值模拟和动力降尺度中的应用.文章最后指出当前区域海气耦合模式发展中有待解决的一些问题,并就未来的发展方向提出了几点建议和想法.

References

[1]	1 陈克明, 金向泽, 张学洪. 关于海气耦合模式气候漂移及敏感性的一点探讨. 海洋学报, 1997, 19: 38-51
[2]	2 Manabe S, Bryan K. Climate calculation with a combined ocean-atmosphere model. J Atmos Sci, 1969, 26: 768-789
[3]	3 Manabe S, Bryan K, Spelman M J. A global ocean-atmosphere climate model, Part I: The atmospheric circulation. J Phys Oceanogr, 1975, 5: 3-29？？
[4]	4 Manabe S, Bryan K, Spelman M J. A global ocean-atmosphere model with seasonal variation for future studies of climate sensitivity. Dynam Atmos Oceans, 1979, 3: 393-426？？
[5]	5 Bryan K, Manabe S, Pacanowski R C. A global ocean-atmosphere climate model, Part II: The oceanic circulation. J Phys Oceanogr, 1975, 5: 30-46？？
[6]	6 Washington W M, Semtner A J, Meehl G A, et al. General circulation experiment with a coupled atmosphere, ocean and sea ice model. J Phys Oceanogr, 1980, 10: 1887-1908？？
[7]	7 周天军, 俞永强, 宇如聪, 等. 气候系统模式发展中的耦合器研制问题. 大气科学, 2004, 28: 993-1007
[8]	8 王斌, 周天军, 俞永强, 等. 地球系统模式发展展望. 气象学报, 2008, 66: 857-869
[9]	9 Zeng Q C, Yuan C G, Zhang X H, et al. Documentation of IAP two-level atmospheric general circulation model. DOE/ER/60314-H1, TR044, 1989. 383
[10]	10 Zhang X H. Dynamic framework of IAP nine-level atmospheric general circulation model. Adv Atmos Sci, 1990, 7: 66-77
[11]	11 毕训强. IAP九层大气环流模式及气候数值模拟. 博士学位论文. 北京: 中国科学院大气物理研究所, 1993
[12]	12 Liang X Z. Description of a nine-level grid poing general circulation model. Adv Atmos Sci, 1996, 13: 269-298
[13]	13 Zhang X H, Liang X Z. A numerical world ocean general circulation model. Adv Atmos Sci, 1989, 6: 43-61
[14]	14 Zhang X H, Bao N, Yu R C, et al. Coupling scheme experiments based on an atmospheric and an oceanic GCM. Chin J Atmos Sci, 1992, 16: 129-144
[15]	15 陈克明. IAP全球海气耦合环流模式的改进及温室气候引起气候变化的数值模拟研究. 博士学位论文. 北京: 中国科学院大气物理研究所, 1994
[16]	16 Liu H, Jin X Z, Zhang X H, et al. A coupling experiment of an atmosphere and an ocean model with a monthly anomaly exchange scheme. Adv Atmos Sci, 1996, 13: 133-146？？
[17]	17 吴国雄, 张学洪, 刘辉, 等. LASG全球海洋大气陆面系统模式(GOALS/LASG)及其模拟研究. 应用气象学报, 1997, 8(增刊): 15-28
[18]	18 Yu Y Q, Yu R C, Zhang X H, et al. A flexible coupled ocean-atmosphere general circulation model. Adv Atmos Sci, 2002, 19: 169-190？？
[19]	21 Yu Y Q, Zheng W P, Wang B, et al. Versions g1.0 and g1.1 of the LASG/IAP Flexible Global Ocean-Atmosphere-Land System model. Adv Atmos Sci, 2011, 28: 99-117
[20]	22 丁一汇, 李清泉, 李维京, 等. 中国业务动力季节预报的进展. 气象学报, 2004, 62: 598-612
[21]	23 闵锦忠, 孙照渤, 朱伟军. 海气耦合环流模式及耦合技术的研究. 南京气象学院学报, 2000, 23: 449-458
[22]	24 Zebiak S E, Cane M A. A model El Nino-Southern oscillation. Mon Weather Rev, 1987, 115: 2262-2278？？
[23]	25 徐建霞, 孙照渤, 雷兆崇. 用海-气耦合模式作季风季节平均环流的数值试验. 南京气象学院学报, 1992, 15: 332-341
[24]	26 Boville B A. The NCAR climate system model version 1. BMRC Res Rep, 1998, 69: 5-7
[25]	27 Collins W D, Bitz C M, Blackmon M L, et al. The Community Climate System Model Version 3 (CCSM3). J Clim, 2006, 19: 2122-2143？？
[26]	28 Matsuno T, Kawamiya M, Sudo K, et al. Development of an Integrated Earth System Model for prediction of environmental changes. In: Annual Report of the Earth Simulator Center. 2005
[27]	29 Seo H, Miller A J, Roads J O. The scripps coupled ocean-atmosphere regional (SCOAR) model with applications in the Eastern Pacific sector. J Clim, 2007, 20: 381-402？？
[28]	30 Neelin J D, Latif M, Allaart M A F, et al. Tropical air-sea interaction in general circulation models. Clim Dyn, 1992, 7: 73-104
[29]	31 Hodur R M. The Naval Research Laboratory’s Coupled Ocean/Atmosphere Mesoscale Prediction System (COAMPS). Mon Weather Rev, 1997, 125: 1414-1430？？
[30]	32 Knutson T R, Tulyea R E, Kurihara Y. Simulated increase of hurricane intensities in CO2-warmed climate. Science, 1998, 279: 1018-1020？？
[31]	33 Gustafsson N, Nyberg L, Omstedt A. Coupling of a high-resolution atmospheric model and an ocean model for the Baltic Sea. Mon Weather Rev, 1998, 126: 2822-2846？？
[32]	34 Hagedorn R, Lehmann A, Jacob D. A coupled high resolution atmosphere-ocean model for the BALTEX region. Meteorol Z, 2000, 9: 7-20
[33]	35 Xue H J, Pan Z Q, John M, et al. A 2D coupled atmosphere-ocean model study of air-sea interactions during a cold air outbreak over the Gulf stream. Mon Weather Rev, 2000, 128: 973-996？？
[34]	36 Bao J W, Wilczak J M, Choi J K, et al. Numerical simulations of air-sea interactions under high wind conditions using a coupled model: A study of hurricane development. Mon Weather Rev, 2000, 128: 2190-2210？？
[35]	48 Sasaki H, Kurihara K, Takayabu I, et al. Preliminary results from the coupled atmosphere-ocean regional climate model at the Meteorological Research Institute. J Meteorol Soc Jpn, 2006, 84: 389-403？？
[36]	49 姚素香, 张耀存. 区域海气耦合模式对中国夏季降水的模拟. 气象学报, 2008, 66: 131-142
[37]	50 关皓, 周林, 史尧, 等. 利用jason_1资料验证区域海气耦合模式模拟台风浪的有效性. 海洋预报, 2009, 26: 84-93
[38]	51 Warner J C, Armstrong B, He R Y, et al. Development of a Coupled Ocean-Atmosphere-Wave-Sediment Transport (COAWST) modeling system. Ocean Modelling, 2010, 35: 230-244？？
[39]	52 Fang Y J, Zhang Y C, Tang J P, et al. A regional air-sea coupled model and its application over east asia in the summer of 2000. Adv Atms Sci, 2010, 27: 583-593？？
[40]	53 李涛, 周广庆. 一个东亚区域海气耦合模式初步结果. 科学通报, 2010, 55: 808-819
[41]	54 孙一妹, 费建芳, 程小平, 等. WRF_ROMS-1.2中尺度海气耦合模式简介. 海洋预报, 2010, 27: 82-88
[42]	55 Xue M, Droegemeier K K, Wong V. The Advanced Regional Prediction System (ARPS)—A multi-scale nonhydrostatic atmospheric simulation and prediction model. PARTI: Model dynamics and verification. Meteorol Atmos Phys, 2000, 75: 161-193？？
[43]	56 Li Y, Xue H, John M B. Air-sea interactions during the passage of a winter storm over the Gulf Stream: A three-dimensional coupled atmosphere-ocean model study. J Geophys Res, 2002, 107: 3200, doi: 10.1029/2001JC001161？？
[44]	57 Xie L, Leonard J, Pietrafesa. Coastal ocean-atmosphere coupling. Amer Geophys Union, 2001, 5: 101-123
[45]	58 严邦良, 黄荣辉, 张人禾. 一个可描写ENSO循环基本特点的简单热带海气耦合模式. 大气科学, 2002, 26: 193-205
[46]	59 闵锦忠, 孙照渤, 曾刚, 等. 全球海气耦合模式系统(NIM/COAMS)一种新的再分析同步耦合方案. 南京气象学院学报, 2005, 28: 601-608
[47]	60 秦正坤, 孙照渤, 林朝晖, 等. 一个海气耦合模式对东亚夏季风气候预测潜力的评估. 气候与环境研究, 2007, 12: 426-436
[48]	61 汪方, 丁一汇, 徐影. 辐射参数化方案对一个海气耦合模式云和辐射模拟的影响. 应用气象学报, 2007, 18: 257-265
[49]	62 林万涛, 张博, 林一骅. 简单海气耦合模式大气运动方程的非线性对ENSO循环模拟的影响. 气候与环境研究, 2008, 13: 253-259
[50]	63 张莉, 丁一汇. 全球海气耦合模式对我国极端强降水模拟检验. 应用气象学报, 2008, 19: 760-769
[51]	64 王志仁, 姜达庸, 包澄澜. 一个区域耦合海气模式及其试验. 海洋学报, 1995, 17: 50-58
[52]	65 吕世华, 陈玉春, 朱伯承. 南海海域海-气耦合模式及其数值模拟试验. 高原气象, 2000, 19: 415-426
[53]	66 任雪娟. 南海季风区海气相互作用研究、区域海气耦合模式的研制及夏季风的模拟. 博士学位论文. 南京: 南京大学大气科学系, 2000
[54]	67 Ren X J, Qian Y F. A coupled regional air-sea model, its performance and climate drift in simulation of the East Asian summer monsoon in 1998. Int J Climatol, 2005, 25: 679-692
[55]	75 Sausen R, Barthel K, Hasselmann K. Coupled ocean-atmosphere models with flux correction. Clim Dyn, 1988, 2: 145-163？？
[56]	76 Anthes R A, Hsie E Y, Kuo Y H. Descript ion of the PENN State/NCAR mesoscale model version 4 (MM4). NCAR Technical Note, 1987, NCAR/TN-282+STR, 66
[57]	77 Giorgi F, Marinucci M R. An investigation of the sensitivity of simulated precipitation to model resolution and its implications for climate studies. Mon Weather Rev, 1996, 124: 148-166？？
[58]	78 Warner T T, Peterson R A, Treadon R E. A tutorial on lateral boundary conditions as a basic and potentially serious limitation to regional numerical weather prediction. Bull Am Meteorol Soc, 1997, 78: 2599-2617？？
[59]	79 Harrison E, Elsberry R. A method for incorporating nested finite grids in the solution of systems of geophysical equations. J Atmos Sci, 1972, 29: 1235-1245？？
[60]	80 Phillips N A, Shukla J. On the strategy of combining coarse and fine grid meshes in numerical weather prediction. J Appl Meteorol, 1973, 12: 763-770？？
[61]	81 Staniforth A N, Mitchell H L. A variable-resolution finite-element technique for regional forecasting with the primitive equations. Mon Weather Rev, 1978, 106: 439-447？？
[62]	82 Hill G. Grid telescoping in numerical weather prediction. J Appl Meteorol, 1968, 7: 29-38？？
[63]	83 Wang H H, Halpern P. Experiments with a regional fine-mesh prediction model. J Appl Meteorol, 1970, 9: 543-553
[64]	84 Kesel P G, Winninghoff F J. The fleet numerical weather central operational primitive-equation model. Mon Weather Rev, 1972, 100: 360-373？？
[65]	85 王继光, 魏绍远, 章震越. 有限区域套网格数值预报模式的侧边界处理技术的研究与试验. 气象科学, 1992, 12: 371-379
[66]	86 Perkey D J, Kreitzberg C W. A time-dependent lateral boundary scheme for limited-area primitive equation models. Mon Weather Rev, 1976, 104: 744-755？？
[67]	87 Davies H C. A lateral boundary condition for multi-level prediction models. Q J R Meteorol Soc, 1976, 102: 405-418
[68]	88 Orlanski I. A simple boundary condition for unbounded hyperbolic flow. J Comput Phys, 1976, 2: 251-269
[69]	89 陈月娟. 辐射边界条件在局地模式中的试验. 高原气象, 1987, 2: 111-116
[70]	90 储敏, 徐永福. 区域海洋模式中的开边界问题. 海洋科学, 2009, 33: 112-117
[71]	91 Treguier A M, Barnier B, Miranda A P, et al. An eddy-permitting model of the Atlantic circulation: Evaluating open boundary conditions. J Geophy Res, 2001, 106: 22115-22129？？
[72]	92 Marchesiello P, McWilliams J C, Shchepetkin A. Open boundary conditions for long-term integration of regional oceanic models. Ocean Modelling, 2001, 3: 1-20？？
[73]	93 Drennan W M, Taylor P K, Yelland M J. Parameterizing the sea surface eoughness. J Phys Oceanogr, 2005, 35: 835-848？？
[74]	94 Hwang P A. Influence of wavelength on the parameterization of drag coefficient and surface roughness. J Phys Oceanogr, 2004, 60: 835-841
[75]	95 Hwang P A. Altimeter measurements of wind and wave modulation by the Kuroshio in the Yellow and East China seas. J Phys Oceanogr, 2005, 61: 987-993？？
[76]	96 Hsu S A. A dynamic roughness equation and its application to wind strss determination at the air-sea interface. J Phys Oceanogr, 1974, 4: 116-120？？
[77]	97 Donelan M A, Dobson F W, Smith S D, et al. On the dependence of sea surface roughness on wave development. J Phys Oceanogr, 1993, 23: 2143-2149 ？？
[78]	98 Donelan M A, Drennan W M, Magnusson A K. Nonstationary analysis of the directional properties of propagating waves. J Phys Oceanogr, 1996, 26: 1901-1914？？
[79]	99 Smith S D, Anderson R J, Oost W A, et al. Sea surface wind stress and drag coefficients: The HEXOS results. Bound-Lay Meteorol, 1992, 60: 109-142？？
[80]	100 Johnson H K, H？jstrup J, Vested H J, et al. On the dependence of sea surface roughness on wind waves. J Phys Oceanogr, 1998, 28: 1702-1716？？
[81]	101 Johnson H K, Vested H J, Hersbach H, et al. The coupling between wind and waves in the WAM model. J Atmo Ocean Tech, 1999, 16: 1780-1790？？
[82]	102 Taylor P K, Yelland M J. The dependence of sea surface roughness on the height and steepness of the waves. J Phys Oceanogr, 2001, 31: 572-590？？
[83]	103 Oost W A, Komen G J, Jacobs C M J, et al. New evidence for a relation between wind stress and wave age from measurements during ASGAMAGE. Bound-Lay Meteorol, 2002, 103: 409-438？？
[84]	104 Fairall C W, Bradley E F, Hare J E, et al. Bulk parameterization of air-sea fluxes: Updates and verification for the COARE algorithm. J Clim, 2003, 16: 571-591？？
[85]	105 Drennan W M, Graber H C, Hauser D, et al. On the wave age dependence of wind stress over pure wind seas. J Geophys Res, 2003, 108: 8062, doi: 10.1029/2000JC000715
[86]	106 Lange B, Johnson H K, Larsen S, et al. On detection of a wave age dependency for the sea surface roughness. J Phys Oceanogr, 2004, 34: 1441-1458？？
[87]	107 潘玉萍, 沙文钰, 王巨华, 等. 发展新型的海面空气动力学粗糙度参数化方案. 自然科学进展, 2007, 17: 1069-1077
[88]	108 Andreas E L. The temperature of evaporating sea spray droplets. J Atmos Sci, 1995, 52: 852-862？？
[89]	109 Andreas E L. A new sea spray generation function for wind speeds up to 32 m s1. J Phys Oceanogr, 1998, 28: 2175-2184 ？？
[90]	110 Kepert J D. Comments on “The Temperature of Evaporating Sea Spray Droplets”. J Atmos Sci, 1996, 53: 1634-1641？？
[91]	111 Wu J. Concentrations of sea-spray droplets at various wind velocities: Separating productions through bubble bursting and wind tearing. J Phys Oceanogr, 2000, 30: 195-200？？
[92]	112 Meirink J F, Makin V K. The impact of sea spray evaporation in a numerical weather prediction model. J Atmos Sci, 2001, 58: 3626-3638？？
[93]	113 Wang Y Q, Kepert J D, Holland G J. The effect of sea spray evaporation on tropical cyclone boundary layer structure and intensity. Mon Weather Rev, 2001, 129: 2481-2500？？
[94]	114 Andreas E L, Emanuel K A. Effects of sea spray on tropical cyclone intensity. J Atmos Sci, 2001, 58: 3741-3751？？
[95]	115 Zhang W Q, Perrie W, Li W B. Impacts of waves and sea spray on midlatitude storm structure and intensity. Mon Weather Rev, 2006, 134: 2418-2442？？
[96]	116 Zhang, W Q, Perrie W. The influence of air-sea roughness, sea spray, and storm translation speed on waves in North Atlantic storms. J Phys Oceanogr, 2008, 38: 817-839？？
[97]	117 Gall J S, Frank W M, Kwon Y. Effects of sea spray on tropical cyclones simulated under idealized conditions. Mon Weather Rev, 2008, 136: 1686-1705？？
[98]	118 Andreas E L, Persson P O G, Hare J E. A Bulk turbulent air-sea flux algorithm for high-wind, spray conditions. J Phys Oceanogr, 2008, 38: 1581-1596？？
[99]	119 Andreas E L. Spray-mediated enthalpy flux to the atmosphere and salt flux to the ocean in high winds. J Phys Oceanogr, 2010, 40: 608-619？？
[100]	120 Lynch A H, Chapman W L, Walsh J E, et al. Development of a regional climate model of the western Arctic. J Clim, 1995, 8: 1555-1570？？
[101]	121 Hasselmann K. Ocean circulation and climate change. Tellus, 1991, 43: 82-103
[102]	156 Xie S P, Miyama T, Wang Y, et al. A regional ocean-atmosphere model for Eastern Pacific climate: Toward reducing tropical biases. J Clim, 2007, 20: 1504-1522？？
[103]	157 Mikolajewicz U, Sein D V, Jacob D, et al. Simulating Arctic sea ice variability with a coupled regional atmosphere-ocean-sea ice model. Meteorol Z, 2005, 14: 793-800？？
[104]	158 Knutson T R, Tuleya R E. Impact of CO2-induce dwarming on simulated hurricane intensity and precipitation: Sensitivity to the choice of climate model and convective parameterization. J Clim, 2004, 17: 3477-3495？？
[105]	19 周天军, 王在志, 宇如聪, 等. 基于LASG/ IAP 大气环流谱模式的气候系统模式. 气象学报, 2005, 63: 702-715
[106]	20 Yu Y Q, Zheng W P, Liu H L, et al. The LASG coupled climate system model FGCM-1.0. Chin J Geophys, 2007, 50: 1454-1455
[107]	37 任雪娟, 钱永甫. 区域海气耦合模式对1998年5-8月东亚近海海况的模拟研究. 气候与环境研究, 2000, 5: 482-485
[108]	38 D？scher R, Willén U, Jones C, et al. The development of the regional coupled ocean-atmosphere model RCAO. Boreal Environ Res, 2002, 7: 183-192
[109]	39 Perrie W, Ren X J, Zhang W Q, et al. Simulation of extratropical Hurricane Gustav using a coupled atmosphere-ocean-sea spray model. Geophys Res Lett, 2004, 31: L03110, doi: 10.1029/2003GL018571？？
[110]	40 Perrie W, Zhang W Q, Andreas E L, et al. Sea spray impacts on intensifying midlatitude cyclones. J Atmos Sci, 2005, 62: 1867-1883？？
[111]	41 Schrum C, Hübner U, Jacob D, et al. A coupled atmosphere-ice-ocean model for the North Sea and Baltic Sea. Clim Dyn, 2003, 21: 131-141？？
[112]	42 Alves O, Wang G, Zhong A, et al. POAMA: Bureau of Meteorology operational coupled model seasonal forecast system. Proceedings of the ECMWF Workshop on the Role of the Upper Ocean in Medium and Extended Range Forecasting, 2002
[113]	43 亓春霞. 中尺度海-气耦合模式MM5V3/ECOM-si对黄东海入海气旋的模拟研究. 博士学位论文. 湖北: 武汉理工大学交通信息工程及控制系, 2003
[114]	44 Aldrian E, Sein D V, Jacob D, et al. Modeling Indonesian rainfall with a coupled regional model. Clim Dyn, 2005, 25: 1-17？？
[115]	45 Nagai H, Kobayashi T, Tsuduki K, et al. coupled atmosphere, land-surface, hydrology, ocean-wave, and ocean-current models for mesoscale water and energy circulations. In: The 11th Conference on Mesoscale Processes, 2005
[116]	46 黄立文, 邓健, 文元桥, 等. 中国近海中尺度海-气-浪耦合模式系统及台风耦合试验. 见: 第六次全国动力气象会议论文集. 2005
[117]	47 Pullen J, Doyle J D, Signell R P. Two-way air-sea coupling: A study of the Adriatic. Mon Weather Rev, 2006, 134: 1465-1483？？
[118]	68 Lin H J, Qian Y F, Zhang Y C, et al. A regional coupled air-ocean wave model and the simulation of the South China sea summer monsoon in 1998. Int J Climatol, 2006, 6: 2041-2056
[119]	69 王志福, 钱永甫, 林惠娟. 区域海气耦合模式对我国极端降水模拟分析. 高原气象, 2008, 27: 113-121
[120]	70 谢坤, 任雪娟, 张耀存, 等. 区域海气耦合模式对华北夏季大气水汽输送模拟结果的检验及其与单独气候模式的比较分析. 气象学报, 2009, 67: 1002-1012
[121]	71 宇如聪, 薛纪善, 徐幼平. AREMS中尺度暴雨数值预报模式系统. 北京: 气象出版社, 2004
[122]	72 黄立文. 中尺度耦合模式LASG-MCM在黄东海区域海-气相互作用研究中的应用. 见: 大气科学和地球流体力学数值模拟国家重点实验室(LASG)会议论文集, 2002
[123]	73 蒋小平, 刘春霞, 费志宾. 一个中尺度海-气耦合模式的研制. 广东气象, 2009, 31: 1-3
[124]	74 蒋小平, 刘春霞, 齐义泉. 用一个海-气耦合模式对台风Krovanh的模拟. 大气科学, 2009, 33: 99-108
[125]	122 Ly L N. A numerical coupled model for studying air-sea-wave interaction. Phys Fluids, 1995, 7: 2396-2406？？
[126]	123 Powers J G, Stoelinga M T. A coupled air-sea mesoscale model: Experiments in atmospheric sensitivity to marine roughness. Mon Weather Rev, 2000, 128: 208-228？？
[127]	124 Doyle J D. Coupled atmosphere-ocean wave simulations under high wind conditions. Mon Weather Rev, 2002, 130: 3087-3099？？
[128]	125 Chen S S, Zhao W, Donelan M A, et al. The CBLAST-hurricane program and the next-generation fully coupled atmosphere-wave-ocean models for hurricane research and prediction. Bull Am Meteorol Soc, 2007, 88: 311-317？？
[129]	126 文元桥, 黄立文, 余胜生, 等. 基于移动代理技术的海-气-浪耦合模拟系统. 武汉理工大学学报, 2006, 28: 125-127
[130]	127 Wen Y Q, Huang L W, Deng J, et al. Franework of distributed coupled atmosphere-ocean-wave modeling system. Adv Atmos Sci, 2006, 23: 442-448？？
[131]	128 Zhang J F, Huang L W, Wen Y Q, et al. Implementation of a distributed atmosphere-wave-ocean coupling model: Typhoon wave simulation in the China seas. In: International Symposium on Distributed Computing and Applications for Business, Engineering and Sciences. Hangzhou, October 12, 2006
[132]	129 Zhang J F, Huang L W, Wen Y Q, et al. A distributed coupled atmosphere-wave-ocean model for typhoon wave numerical simulation. Int J Comput Math, 2008, doi: 10.1080/ 00207160802047632
[133]	130 Le Dimet F X, Talagrand O. Variational algorithms for analysis and assimilation of meteorological observations: Theoretical aspects. Tellus, 1986, 38(A): 97-110
[134]	131 Derber J C. Variational four-dimensional analysis using quasi-geostrophic constraints. Mon Weather Rev, 1987, 115: 998-1008？？
[135]	132 Talagrand O, Courtier P. Variational assimilation of meteorological observations with the adjoint vorticity equation. Part I: Theory. Q J R Meteorol Soc, 1987, 113: 1311-1328？？
[136]	133 Courtier P, Thepaut J N, Hollingsworth A. A strategy for operational implementation of 4D-Var, using an incremental approach. Q J R Meteorol Soc, 1994, 120: 1367-1388？？
[137]	134 Peng S Q, Zou X L. Assimilation of ground-based GPS zenith total delay and rain gauge precipitation observations using 4D-Var and their impact on short-range QPF. J Meteorol Soc Jpn, 2004, 82: 491-506？？
[138]	135 Peng S Q, Xie L A. Effect of determining initial conditions by four-dimensional variational data assimilation on storm surge forecasting. Ocean Modelling, 2006, 14: 1-18？？
[139]	136 Huang X Y, Coauthors. Four-dimensional variational data assimilation for WRF: Formulation and preliminary results. Mon Weather Rev, 2009, 137: 299-314？？
[140]	137 Evensen G. Sequential data assimilation with a nonlinear quasi-geostrophic model using Monte Carlo methods to forecast error statistics. J Geophys Res, 1994, 99(C5): 10143-10162
[141]	138 Evensen G. The ensemble Kalman filter: Theoretical formulation and practical implementation. Ocean Dyn, 2003, 53: 343-367？？
[142]	139 Houtekamer P L, Mitchell H L. Data assimilation using an ensemble Kalman filter technique. Mon Weather Rev, 1998, 126: 796-811？？
[143]	140 Houtekamer P L, Mitchel H L. Ensemble Kalman filtering. Q J R Meteorol Soc, 2005, 131: 3269-3289？？
[144]	141 Anderson J L. An ensemble adjustment Kalman filter for data assimilation. Mon Weather Rev, 2001, 129: 2884-2903？？
[145]	142 Hamill T M. Ensemble-based atmospheric data assimilation. In: Palmer T N, Hagedorn R, eds. Predictability of Weather and Climate. Cambridge: Cambridge Press, 2006. 124-156
[146]	143 Meng Z Y, Zhang F Q. Tests of an ensemble Kalman filter for mesoscale and regional-scale data assimilation. Part III: Comparison with 3DVAR in a real-data case study. Mon Weather Rev, 2008, 136: 522-540
[147]	144 Torn R D. Performance of a mesoscale ensemble Kalman filter (EnKF) during the NOAA high-resolution hurricane test. Mon Weather Rev, 2010, 138: 4375-4392？？
[148]	145 Chen D, Zebiak S E, Busalacchi A J, et al. An improved procedure for El Nino forecasting: Implications for predictability. Science, 1995, 269: 1699-1702？？
[149]	146 Chen D, Cane M A, Zebiak S E, et al. The impact of sea level data assimilation on the Lamont model prediction of the 1997/98 El Nino. Geophys Res Lett, 1998, 25: 2837-2840？？
[150]	147 Ballabrera-Poy J, Busalacchi A J, Murtugudde R. Application of a reduced-order Kalman filter to initialize a coupled atmosphere-ocean model: Impact on the prediction of El Ni？o. J Clim, 2001, 14: 1720-1737？？
[151]	148 Zhang S, Harrison M J, Rosati A, et al. System design and evaluation of coupled ensemble data assimilation for global oceanic climate studies. Mon Weather Rev, 2007, 135: 3541-3564？？
[152]	149 Zhang S, Rosati A, Harrison M J. Detection of multidecadal oceanic variability by ocean data assimilation in the context of a “perfect” coupled model. J Geophys Res, 2009, 114: C12018, doi: 10.1029/2008JC005261 ？？
[153]	150 Zhang S, Rosati A. An inflated ensemble filter for ocean data assimilation with a biased coupled GCM. Mon Weather Rev, 2010, 138: 3905-3931？？
[154]	151 Bender M A, Ginis I, kurihara Y. Numerical simulations of tropical cyclone-ocean interaction with a high-resolution coupled model. J Geophys Res, 1993, 98: 23245-23263？？
[155]	152 Bender M A, Ginis I. Real-case simulations of hurricane-ocean interaction using a high-resolution coupled model: Effects on hurricane intensity. Mon Weather Rev, 2000, 128: 917-946？？
[156]	153 Bender M A, Ginis I, Tuleya R E, et al. The operational GFDL coupled hurricane-ocean prediction system and a summary of its performance. Mon Weather Rev, 2007, 135: 3965-3989？？
[157]	154 Loglisci N, Qian M W, Rachev N, et al. Development of an atmosphere-ocean coupled model and its application over the Adriatic Seaduring a severe weather event of bora wind. J Geophys Res, 2004, 109: D01102, doi: 10.1029/2003JD003956
[158]	155 Huang B, Schopf P S, Shukla J. Intrinsic ocean-atmosphere variability of the tropical Atlantic Ocean. J Clim, 2004, 17: 2058-2077？？
[159]	159 Emanuel K. Climate and tropical cyclone activity: A new model downscaling approach. J Clim, 2006, 19: 4797-4802？？
[160]	160 Bender M A, Knutson T R, Tuleya R E, et al. Modeled impact of anthropogenic warming on the frequency of intense Atlantic hurricanes. Science, 2010, 327: 454-458？？
[161]	161 Raisanen J, Hansson U, Ullerstig A, et al. European climate in the late 21st century: Regional simulations with two driving global models and two forcing scenarios. Clim Dyn, 2004, 22: 13-31 ？？
[162]	162 Meier H E M. Baltic Sea climate in the late twenty-first century: A dynamical downscaling approach using two global models and two emission scenarios. Clim Dyn, 2006, 27: 39-68？？

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133