海冰流变学方案对比模拟试验

EXPERIMENTS OF SIMULATION WITH DIFFERENT SEA ICE RHEOLOGY

下载PDF

导出

摘要利用美国麻省理工学院开发的数值模式MITgcm设计了区域冰-洋耦合数值模拟试验,开展了海冰动力学过程中两种流变学方案(黏性-塑性流变学和弹性-黏性-塑性流变学)的对比研究。结果表明,两种方案模拟的海冰内部应力张量分量σ11和σ22总体分布形式相近。冬季,大值区主要位于加拿大北极群岛和格陵兰岛北侧以及格陵兰岛东侧靠近陆地海区。夏季,大值区主要位于加拿大北极群岛和格陵兰岛北侧。但σ12差别较大,可造成海冰相互作用力的明显差异。海冰相互作用力差值矢量在波弗特海区域呈逆时针涡旋分布而在北冰洋内部呈围绕北极点的顺时针涡旋分布,这导致海冰流速差异也出现相似的特点。相比较而言,弹性-黏性-塑性流变学方案对波弗特涡模拟得更好一些。 Numerical experiments on Arctic sea ice were carried out using an ice-ocean coupled model developed by the Massachusetts Institute of Technology （MITgcm）. Special attention was paid to the effects of using two types of sea ice theology, i.e. viscous-plastic rheology and elastic-viscous-plastic rheology. The results indicated that the major disuibution patterns of internal stress components σ11 and σ22 are similar using the two ice rheology schemes. In winter, areas with comparatively large internal stress components are mostly near land north of the Canadian Arctic Archipelago, Greenland and east of Greenland. In summer,, however, areas with comparatively large internal stress components are mostly north of the Canadian Arctic Archipelago and Greenland. The internal stress components σ12 vary greatly in these experiments, contributing to apparent differences in the force of sea-ice interaction. The difference vector in sea-ice interaction force contributing has anticlockwise and clockwise features in the Beaufort Sea and the inner part of the Arctic Oc, ean respectively, leading to similar patterns in differences in sea-ice drift in these two regions. Comparing with observations, it is seen that the EVP theology is more appropriate for simulation of Beaufort Gyre.

作者刘喜迎

机构地区中国科学院大气物理研究所大气科学和地球流体力学数值模拟国家重点实验室解放军理工大学气象学院

出处《极地研究》 CAS CSCD 北大核心 2011年第2期90-97,共8页 Chinese Journal of Polar Research

基金国家自然科学基金项目(40876101) 国家863计划项目(2010AA012304)资助

关键词 MITgcm 冰-洋耦合海冰动力学流变学海冰数值模拟 MITgcm, sea-ice-ocean coupling, sea-ice dynamics, rheology, sea-ice simulation

分类号 P731.15 [天文地球—海洋科学]

引文网络
相关文献

参考文献22

1Rothroek D A. Tile mechanical behavior of pack iee. Annu Rev Earth Planet Sei, 1975,3:317--342.
2Coon M D, Maykut G A, P1itchard R S, et al. Modeling the pack ice as an elastic-plastic material. AIDJEX Bulletin, 1974,24: 1--105.
3Pritchard R S. An elastk-plastic constilutive law for sea ice. J Appl Mech, 1975, 42:379--384.
4Hibler WD Ⅲ. A dynamic thermodynamic sea ice model. J Phys Oceanogr, 1979, 9:817--846.
5Flato G M, Hibler W D. On modeling pack ice as a cavitating fluid. J Phys Oceanogr, 1992, 22:626-651.
6Hunke E C, Dukowicz J K. An elastie-viscous-plastic model for sea ice dynamics. J Phys Oceanogr, 1997, 27:1849--1867.
7Shen H H, ttibler W D, Leppaaranta M. Tile role of floe collisions in sea ice rheology. J Geophys lies, 1987, 92:7085--7096.
8Tremblay I, B, Mysak L A. Modeling sea ice as a granular material, including the dilatancy effect. J Phys Oceanogr, 1997, 27:2342--2360.
9Coon M D, Knoke G S, Echeri D C, el al. The architecture of an anisotropie elastic-plastic sea ice mechanics constitutive law. J Geophys Res, 1998, 103: 21915-21925.
10Ip C F, Hibler W D, F/ato G M. On the effect of heology on seasonal sea-ice simulations. Ann Glaeiol, 1991, 15:17 -25.

二级参考文献30

1陈立奇,赵进平,卞林根,陈波,陈敏,高爱国,高众勇.影响北极地区迅速变化的一些关键过程研究[J].极地研究,2003,15(4):283-302. 被引量：30
2Comiso J.A rapidly declining perennial sea ice cover in the Arctic,Geophys Res Lett,2002,29:1956,doi:10.1029/2002GL015650.
3Comiso J,Parkinson C,Gersten R,et al.Accelerated decline in the Arctic seaice cover,Geophys Res Lett,2008,35:L01703,doi:10.1029/2007GL031972.
4Nghiem S,Rigor I,Perovich D,et al.Rapid reduction of Arctic perennial sea ice.Geophys Res Lett,2007,34:L19504,doi:10.1029/2007GL031138.
5Steele M,Ermold W,Zhang J.Arctic Ocean surface warming trends over the past 100 years.Geophys Res Lett,2008,35:L02614,doi:10.1029/2007GL031651.
6Richter-Menge J,Overland J,Proshutinsky A,et al.State of the Arctic report.NOAA OAR Special Report.Seattle:NOAA/OAR/PMEL,2006.
7Solomon S,Qin D,Manning M,et al.IPCC Forth Assessment Report.Climate Change.The physical science basis.Cambridge:Cambridge University Press,2007:996.
8Meier W,Stroeve J,Fetterer F.Whither Arctic sea ice? A clear signal of decline regionally,seasonally and extending beyond the satellite record.Ann Glac,2007,46:428-434.
9Ebert E E and Curry J A.An intermediate one-dimensional thermodynamic sea ice model for investigating ice-atmosphere interactions.J Geophys Res,1993,98:10085-10109.
10Maslanik J,Fowler C,Stroeve J,et al.A younger,thinner Arctic ice cover:Increased potential for rapid,extensive sea-ice loss.Geophys Res Lett,2007,34:L24501,doi:10.1029/2007GL032043.

共引文献2

1LI Qun,ZHANG Zhanhai,WU Huiding.Interaction of an anticyclonic eddy with sea ice in the western Arctic Ocean:an eddy-resolving model study[J].Acta Oceanologica Sinica,2013,32(3):54-62. 被引量：2
2张云,郭建京,洪中华,韩彦岭.基于GPS反射信号的岸基海冰探测研究[J].极地研究,2014,26(2):262-267. 被引量：5

1T.Gentzis,杨玉峰.有机质类型和基质岩性对成熟度指标的影响——加拿大北极群岛Melville岛的实例[J].国外油气勘探,1994,6(6):680-687.
2季飞,黄建平,管晓丹,冉津江.北美和欧亚大陆冬季快速增温与地表干湿变化[J].气候变化研究进展,2012,8(6):440-447. 被引量：9
3李群,张璐,吴辉碇.一个北极区域冰海耦合模式的设置与应用[J].极地研究,2010,22(1):79-89. 被引量：3
4范超,陈学恩,迟乐泉.台湾岛东北海域潮致内孤立波二维数值模拟[J].中国海洋大学学报（自然科学版）,2015,45(1):9-17.
5邢传玺,黄大吉.冬季黄海暖流西偏机理数值探讨[J].海洋学报,2010,32(6):1-10. 被引量：6
6邹良志.核磁共振测井仪方案对比分析[J].国外测井技术,2013(5):12-16.
7范超,陈学恩,张哲恩.吕宋海峡夏季内潮数值模拟[J].中国海洋大学学报（自然科学版）,2016,46(6):14-20. 被引量：1
8李延兴,胡新康,赵承坤,王敏,郭良迁,徐菊生.GPS跟踪站观测的初步结果所揭示的板内及板缘地壳水平运动[J].地壳形变与地震,1998,18(2):28-34. 被引量：25
9连展,魏泽勋,方国洪,孙宝楠.气候变暖下海面高度变化的数值模拟[J].海洋科学进展,2013,31(4):455-464. 被引量：3
10徐希刚.119b08工作面优化设计的探讨[J].中国科技纵横,2015,0(24):108-108.

极地研究

2011年第2期

浏览历史

内容加载中请稍等...

海冰流变学方案对比模拟试验

参考文献22

二级参考文献30

共引文献2

相关作者

相关机构

相关主题

浏览历史