Effects of Stokes production on summer ocean shelf dynamics 被引量：1

Effects of Stokes production on summer ocean shelf dynamics

下载PDF

导出

摘要 A two-dimensional numerical model,which is configured on the basis of Princeton ocean model（POM）,is used to study the effect of Stokes production（SP） of the turbulent kinetic energy on a density profile and Ekman transport in an idealized shelf region in summer.The energy input from SP is parameterized and included into the Mellor-Yamada turbulence closure submodel.Results reveal that the intensity of wind-driven upwelling fronts near the sea surface is weakened by the SP-associated turbulent kinetic energy input.The vertical eddy viscosity coefficient in the surface boundary layer is enhanced greatly owing to the impact of SP,which decreases the alongshore velocity and changes the distribution of upwelling.In addition,the SP-induced mixing easily suppresses the strong stratification and significantly increases the depth of the upper mixed layer（ML） under strong winds. A two-dimensional numerical model,which is configured on the basis of Princeton ocean model（POM）,is used to study the effect of Stokes production（SP） of the turbulent kinetic energy on a density profile and Ekman transport in an idealized shelf region in summer.The energy input from SP is parameterized and included into the Mellor-Yamada turbulence closure submodel.Results reveal that the intensity of wind-driven upwelling fronts near the sea surface is weakened by the SP-associated turbulent kinetic energy input.The vertical eddy viscosity coefficient in the surface boundary layer is enhanced greatly owing to the impact of SP,which decreases the alongshore velocity and changes the distribution of upwelling.In addition,the SP-induced mixing easily suppresses the strong stratification and significantly increases the depth of the upper mixed layer（ML） under strong winds.

作者 ZHANG Xuefeng HANGuijun WANG Xidong ZHANG Lianxin

机构地区 Key Laboratory of Marine Environmental Information Technology National Marine Data and Information Service

出处《Acta Oceanologica Sinica》 SCIE CAS CSCD 2014年第1期24-34,共11页 海洋学报（英文版）

基金 The National Basic Research Program of China under contract No.2013CB430304 the National Natural Science Foundation of China under contract Nos 41030854 41106005 41176003 and 41206178 the National Science and Technology Support Program of China under contract No.2011BAC03B02-01

关键词 Stokes production POM upper mixed layer UPWELLING Stokes production POM upper mixed layer upwelling

分类号 P731.2 [天文地球—海洋科学]

引文网络
相关文献

参考文献4

1邓增安,谢立安,韩桂军,张学峰,吴克俭.The effect of Coriolis-Stokes forcing on upper ocean circulation in a two-way coupled wave-current model[J].Chinese Journal of Oceanology and Limnology,2012,30(2):321-335. 被引量：5
2孙群,管长龙,宋金宝.Wave breaking on turbulent energy budget in the ocean surface mixed layer[J].Chinese Journal of Oceanology and Limnology,2008,26(1):9-13. 被引量：6
3李爽,宋金宝.The spacing of Langmuir circulation under modest wind[J].Chinese Journal of Oceanology and Limnology,2012,30(4):690-696. 被引量：1
4LI Shuang,SONG Jinbao,FAN Wei.Effect of Langmuir circulation on upper ocean mixing in the South China Sea[J].Acta Oceanologica Sinica,2013,32(3):28-33. 被引量：6

二级参考文献106

1Bye J A T. 1967. The wave-drift current. J. Mar. Res., 25: 95-102.
2Booij N, Ris R C, Holthuijsen L H. 1999. A third-generation wave model for coastal regions. Part I. Model description and validation. J. Geophys. Res., 104(C4): 7 649-7 666.
3Camiel S, Sclavo M, Kantha L H, Clayson C A. 2005. Langmuir cells and mixing in the upper ocean. II Nuovo Clmento, 28: 33-54.
4Deng Z, Xie L, Liu B, Wu K, Zhao D, Yu T. 2009. Coupling winds to ocean surface currents over the global ocean. Ocean Modeling, 29: 261-268.
5Fang G, Zhao B, Zhu Y. 1991. Water volume transport through the Taiwan Strait and the continental shelf of the East China Sea measured with current meters. In: Takano K ed. Oceanography of Asian Marginal Seas. Elsevier, New York. p.345-358.
6Hasselmann K. 1970. Wave-driven inertial oscillations. Geophys. Fluid Dyn., 1: 463-502.
7Hsin Y-C, Wu C-R, Shaw P-T. 2008. Spatial and temporal variations of the Kuroshio east of Taiwan, 1982-2005: a numerical study. J. Geophys. Res., 111: 1-15.
8Huang N E. 1979. On surface drift currents in the ocean. J. Fluid Mech., 91: 191-208.
9Ianniello J P, Garvine R W. 1975. Stokes transport by gravity waves for application to circulation models. J. Phys. Oceanogr., 5: 47-50.
10Jan S, WangJ,'Chem C-S et al. 2002. Seasonal variation of the circulation in the Taiwan Strait. J. Mar. Sys., 35: 249-268.

共引文献14

1张学峰,韩桂军,吴新荣,李威,王东晓.同化海温观测数据研究波浪破碎对海洋上层结构的影响[J].热带海洋学报,2011,30(5):48-54. 被引量：4
2LIN Zhenhua,ZHAO Dongliang,SONG Jinbao.Reconstructing the upper ocean thermal profiles using one-dimensional numerical model[J].Acta Oceanologica Sinica,2012,31(2):9-15.
3张学峰,韩桂军,王东晓,李威,刘克修,马继瑞.垂向混合参数化方案对模拟黄海夏季上层温度结构的影响研究[J].海洋学报,2014,36(3):73-82. 被引量：1
4WANG Zhifeng,WU Kejian,XIA Changshui,ZHANG Xiaoshuang.The impact of surface waves on the mixing of the upper ocean[J].Acta Oceanologica Sinica,2014,33(9):32-39.
5管长龙,张文清,朱冬琳,魏来.上层海洋中浪致混合研究评述——研究进展及存在问题[J].中国海洋大学学报（自然科学版）,2014,44(10):20-24. 被引量：9
6张晓爽,王智峰,王斌,吴克俭,韩桂军,李威.全球Stokes漂流的时空分布特征研究[J].海洋科学,2015,39(1):93-103. 被引量：2
7刘子龙,史剑,蒋国荣.海浪破碎对北太平洋海表面温度模拟的影响[J].海洋科学,2017,41(3):122-129. 被引量：2
8肖林,史剑,蒋国荣,刘子龙.Stokes漂流对北太平洋海表温度的影响研究[J].海洋科学进展,2017,35(4):462-472. 被引量：1
9肖林,史剑,蒋国荣,刘子龙.台风背景下海浪对海表流场和海表温度的影响[J].海洋通报,2018,37(4):396-403. 被引量：7
10肖林,史剑,蒋国荣,刘子龙,张成成.Stokes漂流对全球海表面温度模拟的影响[J].海洋通报,2018,37(1):55-62. 被引量：2

同被引文献25

1乔方利,马建,夏长水,杨永增,袁业立.波浪和潮流混合对黄海、东海夏季温度垂直结构的影响研究[J].自然科学进展,2004,14(12):1434-1441. 被引量：22
2SUNQun,SONGJinbao,GUANChanglong.Simulation of the ocean surface mixed layer under the wave breaking[J].Acta Oceanologica Sinica,2005,24(3):9-15. 被引量：10
3孙群,管长龙,宋金宝.海浪破碎对海洋上混合层中湍能量收支的影响[J].海洋与湖沼,2006,37(1):69-74. 被引量：8
4樊孝鹏,黄大吉,章本照.东海黑潮的气候态数值模拟[J].浙江大学学报（工学版）,2006,40(5):916-920. 被引量：15
5Mellor G L,Sirpa H, Tal E,et al. A generalization of a sigma coordinate model and an intercomparison of model vertical gridsl Mj/ /Ocean Forecas- ting: Conceptual Basis and Application. German: Springer-Verlag, 2002: 55 -72.
6Mellor G L, Yamada T. Development of a turbulence closure models for geophysical fluid problems[J]. Rev Geophys, 1982,20: 851-875.
7Martin P J. Simulation of the mixed layer at OWS November and Papa with several models[J]. J Geophys Res,1985,90:581-597.
8Kitaigorodskii S A, Lumley J L. Wave-turbulence interactions in the upper ocean. Part I: The energy balance of the interacting fields of surface wind waves and wind-induced three-dimensional turbulence[J]. J Phys Oceanogr , 1983,13: 1977 -1987.
9Thorpe S A. Energy loss by breaking waves[J]. J Phys Oceanogr,1993,23: 2498-2502.
10Drennan W M,Oonelan M A, Terray E A,et al. Ocean turbulence dissipation measurements in SWADE[J]. J Phys Oceanogr , 1996,26: 808-815.

引证文献1

1张学峰,韩桂军,王东晓,李威,刘克修,马继瑞.垂向混合参数化方案对模拟黄海夏季上层温度结构的影响研究[J].海洋学报,2014,36(3):73-82. 被引量：1

二级引证文献1

1FAN Maoting,WANG Huizan,ZHANG Weimin,HAN Guijun,WANG Pinqiang.Evaluation of the China Ocean Reanalysis (CORA) in the South China Sea[J].Journal of Oceanology and Limnology,2020,38(6):1640-1653. 被引量：2

1郭飞,侍茂崇,夏综万.琼东沿岸上升流二维数值模型的诊断计算[J].海洋学报,1998,20(6):109-116. 被引量：11
2云蒙山国家地质公园[J].国土资源情报,2014(1).
3李毅能,彭世球,杨威,王东晓.Numerical simulation of the structure and variation of upwelling off the east coast of Hainan Island using QuikSCAT winds[J].Chinese Journal of Oceanology and Limnology,2012,30(6):1068-1081. 被引量：5
4蒋兴文,何光碧,李跃清.AREM模式中引入MYJ边界层方案介绍及其试验[J].高原山地气象研究,2010,30(4):1-7. 被引量：2
5王真,范植松,司宗尚,张善武.内波混合方法与Mellor-Yamada混合方案在黄海和东海夏季温跃层模拟中的比较研究[J].中国海洋大学学报（自然科学版）,2013,43(8):8-14. 被引量：1
6任慧军,詹杰民.黄海冷水团的季节变化特征及其形成机制研究[J].水动力学研究与进展（A辑）,2005,20(z1):887-896. 被引量：39
7Hu Haoguo,Wang Jia.Modeling the ocean circulation in the Bering Sea[J].Chinese Journal of Polar Science,2008,19(2):193-211. 被引量：1
8超值伴侣S280[J].大众摄影（上半月）,2004,0(10):74-74.
9陆雪,高山红,饶莉娟,王永明.春季黄海海雾WRF参数化方案敏感性研究[J].应用气象学报,2014,25(3):312-320. 被引量：38
10WANG Gang,QIAO Fangli,DAI Dejun,HOU Yijun.A possible generation mechanism of the strong current over the northwestern shelf of the South China Sea[J].Acta Oceanologica Sinica,2011,30(3):27-32.

Acta Oceanologica Sinica

2014年第1期

浏览历史

内容加载中请稍等...