Water circulation in Toronto Harbour

IF 0.8 4区环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES

Aquatic Ecosystem Health & Management Pub Date : 2018-07-03 DOI:10.1080/14634988.2018.1500059

Bogdan Hlevca, M. Wells, Liset Cruz Font, S. Doka, R. Portiss, Margaretha A. St. John, S. Cooke

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引用次数: 14

Abstract

We present an overview of physical processes that drive water circulation within the extended system of coastal embayments in the Toronto Harbour. The different water circulation patterns occur at various spatial and temporal scales, and our article provides context for the various efforts to improve water quality by the Toronto and Region Remedial Action Plan. Velocity profiles and water level measurements showed that the harbour’s Helmholtz pumping mode drives a 1-h period oscillation, which can influence flushing of the shallow embayments. This process likely persists year-round and would lead to flushing time-scales of between 1–11 days for these shallow embayments. If this ubiquitous pumping is combined with solar heat fluxes, it partially explains the persistent temperature gradients amongst the shallow embayments. In the larger and deeper (∼10 m) Inner Harbour, the prevailing westerly winds drive most of the mean circulation, with a current entering through the Western Gap and leaving through the Eastern Gap. This wind driven circulation leads to a residence time of water in the Inner Harbour between 7–14 days. In addition, periodic strong and sustained westerly winds can induce frequent upwelling events in Lake Ontario (between 4 to 10 times during the stratified season) that mildly increase the exchange flow and help maintain good water quality by exchange nearshore waters with cleaner hypolimentic waters. The intrusion of cold water into the harbour can also lead to highly variable temperature regimes with sudden drops in temperature that could have negative effects on aquatic organisms.

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多伦多港的水循环

我们概述了推动多伦多港沿海海湾扩展系统内水循环的物理过程。不同的水循环模式发生在不同的空间和时间尺度上，我们的文章为多伦多和地区补救行动计划为改善水质所做的各种努力提供了背景。速度剖面和水位测量表明，港口的亥姆霍兹泵送模式会驱动1小时的周期振荡，这会影响浅水湾的冲刷。这一过程可能全年持续，并将导致这些浅水湾的冲刷时间在1-11天之间。如果这种普遍存在的泵送与太阳热通量相结合，它可以部分解释浅层海湾中持续存在的温度梯度。在更大、更深（~10米）的内港，盛行的西风驱动了大部分平均环流，气流通过西部缺口进入，然后通过东部缺口离开。这种风驱动的环流导致水在内港的停留时间在7-14天之间。此外，周期性的强持续西风会在安大略湖引发频繁的上升流事件（在分层季节发生4到10次），这会温和地增加交换流量，并通过将近岸水域与更清洁的低盐度水域交换来帮助保持良好的水质。冷水入侵港口也会导致温度高度变化，温度突然下降，这可能会对水生生物产生负面影响。

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

Aquatic Ecosystem Health & Management 环境科学-海洋与淡水生物学

CiteScore

1.70

自引率

0.00%

发文量

审稿时长

18-36 weeks

期刊介绍： The journal publishes articles on the following themes and topics: • Original articles focusing on ecosystem-based sciences, ecosystem health and management of marine and aquatic ecosystems • Reviews, invited perspectives and keynote contributions from conferences • Special issues on important emerging topics, themes, and ecosystems (climate change, invasive species, HABs, risk assessment, models)