有河口水坝的河口残余流、沉积物通量和河床水位变化的横向变化:河口类型、水坝位置和排水间隔的作用

IF 2.1 3区 地球科学 Q2 OCEANOGRAPHY
Steven M. Figueroa, Minwoo Son
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引用次数: 0

摘要

在河口修建河口水坝的原因包括淡水、防洪和航运。通过改变潮汐和河流特性,河口大坝可以改变河口的环流和泥沙输运。以往的研究已经对水流和泥沙输运的沿河道变化进行了调查,但对河口大坝引起的跨河道变化还不甚了解。为了加深理解,本研究使用 COAWST 数值模拟系统分析了一个理想化的河口。强分层河口、部分混合河口、周期性分层河口和混合良好河口的模型运行了一年。然后,在修建河口大坝的条件下,再运行一年。针对每种河口类型,研究了在距河口 x = 20、55 和 90 公里处修建河口大坝,淡水排放间隔为 Δt = 0.5、3 和 7 天的方案,并对这些方案进行了比较。结果表明,以河流为主的河口和以潮汐为主的河口表现不同。在以河流为主的河口,由于河口交换流的作用,残余环流趋向于在河道内流入,在滩涂上流出,而次级环流则由于差异平流而呈底层发散状。随着排放间隔的延长,交换流和次级环流的作用逐渐减弱。河道中的沉积物通量占主导地位,尽管交换流较弱,但在较长的排放间隔内,由于大坝的强力排放,河道中的沉积物通量较大,并向海方向流动。在以潮汐为主的河口,由于潮汐引起的环流,残余环流倾向于在滩涂上流入,在河道中流出,由于斯托克斯回流产生的差动平流,次级流为底部汇聚流。当河口大坝靠近河口时,潮汐引起的环流被交换流所取代,二次流变成了底部发散流。在这种情况下,河道中的泥沙通量也占主导地位,由潮汐与剩余水流相互作用产生的潮汐不对称性决定,随着河口附近的河口大坝建成,向海的潮汐诱导环流减少,泥沙通量变为向陆地流动。在河床水位变化方面,沿河道沉积通量的梯度对河口和河口大坝附近河床水位变化的影响最大,而跨河道沉积通量的梯度对河口浅滩沉积的影响最大。这项研究表明,河口大坝的位置和排水间隔可改变河口横向变化,与之前仅基于沿河道过程的分析相比,这项研究加深了我们的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Transverse variability of residual currents, sediment fluxes, and bed level changes in estuaries with an estuarine dam: Role of estuarine type, dam location, and discharge interval

Estuarine dams are constructed in estuaries for reasons such as freshwater, flood control, and navigation. By changing tidal and river properties, estuarine dams can change the circulation and sediment transport in estuaries. Previous studies have investigated the along-channel changes in flow and sediment transport, however across-channel changes due to an estuarine dam are not well understood. To increase our understanding, this study analyzed an idealized estuary using the COAWST numerical modeling system. Models of strongly stratified, partially mixed, periodically stratified, and well-mixed estuaries were run for one year. Then, the models were subject to the construction of an estuarine dam and run for another year. For each estuarine type, scenarios with an estuarine dam at x = 20, 55, and 90 km from the mouth and freshwater discharge intervals of Δt = 0.5, 3, and 7 days were investigated, and the scenarios were compared. The results indicated that the river-dominated and tide-dominated estuaries behaved differently. In river-dominated estuaries, the residual circulation tended to be inflow in the channel and outflow over the shoals due to the estuarine exchange flow, and the secondary circulation was bottom divergent due to differential advection. The exchange flow and secondary circulation were found to weaken with longer discharge interval. The sediment fluxes in the channel were dominant, and, despite the weaker exchange flow, were found to be greater and directed seaward due to strong dam discharge for long discharge intervals. In tide-dominated estuaries, the residual circulation tended to be inflow over the shoals and outflow in the channel due to the tide-induced circulation, and the secondary flow was bottom convergent due to differential advection resulting from Stokes return flow. As the estuarine dam was located nearer to the mouth, the tide-induced circulation was replaced with exchange flow, and the secondary flow became bottom divergent. The sediment fluxes in the channel were dominant in this case as well, and were determined by tidal asymmetry from the interaction of the tides with the residual current, becoming directed landward as the seaward tide-induced circulation decreased with the estuarine dam near the mouth. With respect to bed level change, gradients in along-channel sediment fluxes were found to contribute most to bed level change near the mouth and estuarine dam, whereas gradients in across-channel sediment fluxes contributed most to deposition on the estuarine shoals. This study demonstrates that estuarine dam location and discharge interval can alter estuarine transverse variability and improves our understanding compared to previous analyses based solely on along-channel processes.

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来源期刊
Continental Shelf Research
Continental Shelf Research 地学-海洋学
CiteScore
4.30
自引率
4.30%
发文量
136
审稿时长
6.1 months
期刊介绍: Continental Shelf Research publishes articles dealing with the biological, chemical, geological and physical oceanography of the shallow marine environment, from coastal and estuarine waters out to the shelf break. The continental shelf is a critical environment within the land-ocean continuum, and many processes, functions and problems in the continental shelf are driven by terrestrial inputs transported through the rivers and estuaries to the coastal and continental shelf areas. Manuscripts that deal with these topics must make a clear link to the continental shelf. Examples of research areas include: Physical sedimentology and geomorphology Geochemistry of the coastal ocean (inorganic and organic) Marine environment and anthropogenic effects Interaction of physical dynamics with natural and manmade shoreline features Benthic, phytoplankton and zooplankton ecology Coastal water and sediment quality, and ecosystem health Benthic-pelagic coupling (physical and biogeochemical) Interactions between physical dynamics (waves, currents, mixing, etc.) and biogeochemical cycles Estuarine, coastal and shelf sea modelling and process studies.
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