Secondary Circulation Asymmetry in a Meandering, Partially Stratified Estuary: SECONDARY CIRCULATION ASYMMETRY

Q1 Earth and Planetary Sciences

Journal of Geophysical Research Pub Date : 2018-03-01 DOI:10.1002/2016jc012623

J. Pein, A. Valle‐Levinson, E. Stanev

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引用次数: 22

Abstract

Numerical model experiments are used to study the effects of multiple channel bends on estuarine dynamics and, in particular, on secondary flows. These effects are demonstrated by comparing experiments with two different idealized trumpet-shaped estuaries, one straight and another one with a 8 km meandering section in the middle of the estuary. Meanders complicate the flow field by introducing secondary processes. For instance, meanders increase turbulence and associated mixing locally within the water column, as well as outside the meandering portion. Furthermore, meanders transform up to 30% of the along-channel momentum into secondary circulation. Production of turbulence and secondary currents is different at flood and ebb tidal phases. At flood, meanders lead to unstable stratification and increased turbulence. At ebb, the flow develops a helical pattern and adjusts to the channel curvature with minimal decrease in density stability. The secondary circulation asymmetry is caused by an interplay between the across-channel baroclinic pressure gradient force and the centrifugal force. During ebb both forces enhance each other, whereas they oppose during flood. As a consequence of this interaction between baroclinic forcing and curving morphology, ebb flows and horizontal buoyancy fluxes increase relative to flood. The enhanced ebb dominance shifts a density front toward the mouth of the estuary, thus reducing salt intrusion.

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弯曲、部分分层河口的二次环流不对称性：二次环流非对称性

数值模型实验用于研究多个河道弯曲对河口动力学的影响，特别是对二次流的影响。通过对两个不同的理想化喇叭形河口的实验进行比较，证明了这些效果，一个是直的，另一个是河口中部8公里的曲折段。弯曲通过引入二次过程使流场复杂化。例如，弯曲增加了水柱内部以及弯曲部分外部的局部湍流和相关混合。此外，曲流将高达30%的沿河道动量转化为二次环流。在涨潮和退潮阶段，湍流和二次流的产生是不同的。洪水时，曲流会导致不稳定的分层和湍流的增加。在退潮时，水流形成螺旋状，并根据河道曲率进行调整，密度稳定性下降最小。二次环流的不对称性是由跨通道斜压梯度力和离心力之间的相互作用引起的。在退潮期间，两种力量相互增强，而在洪水期间则相反。由于斜压强迫和弯曲形态之间的相互作用，退潮和水平浮力通量相对于洪水增加。退潮优势的增强使密度锋向河口移动，从而减少了盐的入侵。

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

Journal of Geophysical Research 地学-地球科学综合

CiteScore

5.80

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： Journal of Geophysical Research (JGR) publishes original scientific research on the physical, chemical, and biological processes that contribute to the understanding of the Earth, Sun, and solar system and all of their environments and components. JGR is currently organized into seven disciplinary sections (Atmospheres, Biogeosciences, Earth Surface, Oceans, Planets, Solid Earth, Space Physics). Sections may be added or combined in response to changes in the science.