Wind‐Driven Currents in a “Wide” Narrow Channel, With Application to Douglas Channel, BC

Wind‐Driven Currents in a “Wide” Narrow Channel, With Application to Douglas Channel, BC

This paper applies a structured grid, 3‐Dimensional Regional Ocean Modeling System to examine wind‐driven currents of an idealized stratified channel, representative of Douglas Channel, British Columbia, Canada, where the increased marine activities require an improved understanding of the physical...

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Veröffentlicht in:Journal of geophysical research. Oceans 2022-08, Vol.127 (8), p.n/a
Hauptverfasser: Wan, Di, Hannah, Charles G., Cummins, Patrick F., Foreman, Michael G. G., Dosso, Stan E.
Format: Artikel
Sprache:eng
Schlagworte:
Brackishwater environment
Channel flow
Density
Elevation
Estuaries
Fjords
Geophysics
Mathematical models
Numerical models
Ocean currents
Ocean models
Oceanography
Outflow
Physical oceanography
Scaling
Scaling factors
Slopes
Stratification
Structured grids (mathematics)
Surface boundary layer
Surface layers
Surface wind
Thermal winds
Thickness
Water outflow
Water surface slope
Waterways
Wind
Wind stress
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container_issue 8
container_start_page
container_title Journal of geophysical research. Oceans
container_volume 127
creator Wan, Di
Hannah, Charles G.
Cummins, Patrick F.
Foreman, Michael G. G.
Dosso, Stan E.
description This paper applies a structured grid, 3‐Dimensional Regional Ocean Modeling System to examine wind‐driven currents of an idealized stratified channel, representative of Douglas Channel, British Columbia, Canada, where the increased marine activities require an improved understanding of the physical oceanography. The surface along‐channel elevation slope resulting from the wind stress is strongly affected by the surface stratification and can serve as a proxy for gauging surface stratification in operational systems. In the case of strong surface stratification, due to rotational effects an apparently narrow (width ≪ length) channel can be dynamically wide with pronounced cross‐channel variation. The thickness of the surface wind‐driven layer is scaled using the thermal wind relation, which provides a scaling factor to estimate the thickness of the surface layer. This scaling factor is not restricted to the wind‐driven flow and could be expanded to the surface mean estuarine outflow layers. Plain Language Summary Douglas Channel is the main waterway in the Kitimat fjord system in the northern British Columbia coast. In this paper, we use an idealized numerical model to study the wind‐driven responses in the channel. We find that the surface slope caused by the wind can be used as a proxy to measure how fast density changes from the surface to the deeper water. Model results show that cross‐channel flow differences exist indicating that if the density changes rapidly in the upper layer, narrow channels like Douglas Channel should be considered as wide for us to not neglect cross‐channel variance. A scaling factor is proposed to explain the thickness of the surface layer depth and this could be expanded to estimate mean estuarine outflow layers. Key Points Physically narrow channels can be dynamically wide in the case of strong surface stratification Thermal wind provides a scaling argument for determining the thickness of the surface wind‐driven layer Outflowing surface layer can be thicker than the highly stratified surface layer
doi_str_mv 10.1029/2021JC017887
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The thickness of the surface wind‐driven layer is scaled using the thermal wind relation, which provides a scaling factor to estimate the thickness of the surface layer. This scaling factor is not restricted to the wind‐driven flow and could be expanded to the surface mean estuarine outflow layers. Plain Language Summary Douglas Channel is the main waterway in the Kitimat fjord system in the northern British Columbia coast. In this paper, we use an idealized numerical model to study the wind‐driven responses in the channel. We find that the surface slope caused by the wind can be used as a proxy to measure how fast density changes from the surface to the deeper water. Model results show that cross‐channel flow differences exist indicating that if the density changes rapidly in the upper layer, narrow channels like Douglas Channel should be considered as wide for us to not neglect cross‐channel variance. A scaling factor is proposed to explain the thickness of the surface layer depth and this could be expanded to estimate mean estuarine outflow layers. 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A scaling factor is proposed to explain the thickness of the surface layer depth and this could be expanded to estimate mean estuarine outflow layers. 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In the case of strong surface stratification, due to rotational effects an apparently narrow (width ≪ length) channel can be dynamically wide with pronounced cross‐channel variation. The thickness of the surface wind‐driven layer is scaled using the thermal wind relation, which provides a scaling factor to estimate the thickness of the surface layer. This scaling factor is not restricted to the wind‐driven flow and could be expanded to the surface mean estuarine outflow layers. Plain Language Summary Douglas Channel is the main waterway in the Kitimat fjord system in the northern British Columbia coast. In this paper, we use an idealized numerical model to study the wind‐driven responses in the channel. We find that the surface slope caused by the wind can be used as a proxy to measure how fast density changes from the surface to the deeper water. Model results show that cross‐channel flow differences exist indicating that if the density changes rapidly in the upper layer, narrow channels like Douglas Channel should be considered as wide for us to not neglect cross‐channel variance. A scaling factor is proposed to explain the thickness of the surface layer depth and this could be expanded to estimate mean estuarine outflow layers. 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source Wiley Online Library Free Content; Wiley Online Library All Journals; Alma/SFX Local Collection
subjects Brackishwater environment
Channel flow
Density
Elevation
Estuaries
Fjords
Geophysics
Mathematical models
Numerical models
Ocean currents
Ocean models
Oceanography
Outflow
Physical oceanography
Scaling
Scaling factors
Slopes
Stratification
Structured grids (mathematics)
Surface boundary layer
Surface layers
Surface wind
Thermal winds
Thickness
Water outflow
Water surface slope
Waterways
Wind
Wind stress
title Wind‐Driven Currents in a “Wide” Narrow Channel, With Application to Douglas Channel, BC
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