Spatio‐temporal variability in a mid‐latitude ocean basin subject to periodic wind forcing

IF 1.6 4区地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES

Atmosphere-Ocean Pub Date : 2007-12-01 DOI:10.3137/ao.450404

L. Sushama, Michael Ghil, Kayo Ide

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引用次数: 19

Abstract

Abstract The mid‐latitude ocean's response to time‐dependent zonal wind‐stress forcing is studied using a reduced‐gravity, 1.5‐layer, shallow‐water model in two rectangular ocean basins of different sizes. The small basin is 1000 km × 2000 km and the larger one is 3000 km × 2010 km; the aspect ratio of the larger basin is quite similar to that of the North Atlantic between 20°N and 60°N. The parameter dependence of the model solutions and their spatio‐temporal variability subject to time‐independent wind stress forcing serve as the reference against which the results for time‐dependent forcing are compared. For the time‐dependent forcing case, three zonal‐wind profiles that mimic the seasonal cycle are considered in this study: (1) a fixed‐profile wind‐stress forcing with periodically varying intensity; (2) a wind‐stress profile with fixed intensity, but north–south migration of the mid‐latitude westerly wind maximum; and (3) a north–south migrating profile with periodically varying intensity. Results of the small‐basin simulations show the intrinsic variability found for time‐independent forcing to persist when the intensity of the wind forcing varies periodically. It thus appears that the physics behind the upper ocean's variability is mainly controlled by internal dynamics, although the solutions’ spatial patterns are now more complex, due to the interaction between the external and internal modes of variability. The north–south migration of wind forcing, however, does inhibit the inertial recirculation; its suppression increases with the amplitude of north–south migration in the wind‐stress forcing. Model solutions in the larger rectangular basin and at smaller viscosity exhibit more realistic recirculation gyres, with a small meridional‐to‐zonal aspect ratio, and an elongated eastward jet; the low‐frequency variability of these solutions is dominated by periodicities of 14 and 6–7 years. Simulations performed in this setting with a wind‐stress profile that involves seasonal variations of realistic amplitude in both the intensity and the position of the atmospheric jet show the seven‐year periodicity in the oceanic circulation to be robust. The intrinsic variability is reinforced by the periodic variations in the jet's intensity and weakened by periodic variations in the meridional position; the two effects cancel, roughly speaking, thus preserving the overall characteristics of the seven‐year mode.

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受周期性风强迫影响的中纬度海洋盆地的时空变率

摘要在两个不同大小的矩形海洋盆地中，利用1.5层减重浅水模式研究了中纬度海洋对随时间变化的纬向风应力的响应。小流域面积为1000公里× 2000公里，大流域面积为3000公里× 2010公里;在20°N ~ 60°N之间，大盆地的纵横比与北大西洋的纵横比非常相似。模式解的参数依赖性及其受时间无关风应力影响的时空变异性可作为比较时间无关风应力结果的参考。对于时间依赖的强迫情况，本研究考虑了模拟季节周期的三个纬向风廓线:(1)强度周期性变化的固定廓线风应力强迫;(2)强度固定，但以中纬度西风南北向迁移为主的风应力廓线;(3)强度周期性变化的南北迁移剖面。小盆地模拟的结果表明，当风强迫强度周期性变化时，与时间无关的强迫的内在变率仍然存在。因此，上层海洋变率背后的物理学似乎主要由内部动力学控制，尽管由于外部和内部变率模式之间的相互作用，解决方案的空间模式现在更加复杂。南北向风强迫的迁移对惯性再环流有抑制作用;在风应力强迫中，其抑制作用随南北向迁移的幅度增大而增大。在较大的矩形盆地和较小的粘度下，模型解表现出更真实的再循环环流，具有较小的经向-纬向长径比和拉长的向东射流;这些溶液的低频变异性以14年和6-7年的周期性为主。在这种情况下，用风应力剖面进行模拟，其中包括大气急流强度和位置的实际振幅的季节性变化，结果表明，海洋环流的七年周期性很强。射流强度的周期性变化增强了固有变异性，经向位置的周期性变化减弱了固有变异性;粗略地说，这两种效应相互抵消，从而保留了七年模式的总体特征。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Atmosphere-Ocean 地学-海洋学

CiteScore

2.50

自引率

16.70%

发文量

审稿时长

>12 weeks

期刊介绍： Atmosphere-Ocean is the principal scientific journal of the Canadian Meteorological and Oceanographic Society (CMOS). It contains results of original research, survey articles, notes and comments on published papers in all fields of the atmospheric, oceanographic and hydrological sciences. Arctic, coastal and mid- to high-latitude regions are areas of particular interest. Applied or fundamental research contributions in English or French on the following topics are welcomed: climate and climatology; observation technology, remote sensing; forecasting, modelling, numerical methods; physics, dynamics, chemistry, biogeochemistry; boundary layers, pollution, aerosols; circulation, cloud physics, hydrology, air-sea interactions; waves, ice, energy exchange and related environmental topics.