Large‐scale turbulent mixing at a mesoscale confluence assessed through drone imagery and eddy‐resolved modelling

Duguay, Jason; Biron, Pascale M.; Bélanger, Thomas-Buffin

doi:10.1002/esp.5251

Cited by 11 publications

(12 citation statements)

References 61 publications

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“…The variety of mixing patterns observed in the postconfluent reaches of natural confluences (Biron et al., 2019; Duguay et al., 2022; Horna‐Munoz et al., 2020; Lane et al., 2008; Sukhodolov & Sukhodolova, 2019) is largely attributed to the complex and little understood interactions of the four mentioned forms of coherent flow structures (KH instabilities, helical cells, episodic pulses, and SOVs). Therefore, a deeper understanding of SOVs, with a specific focus on how they form and interact with other coherent flow structures is necessary if confluence hydrodynamics are to be understood.…”

Section: Introductionmentioning

confidence: 99%

“…Inherently a feature of the subsurface flow, SOVs are difficult to view: The joining rivers often lack a turbidity contrast, rendering the SOVs “invisible” in aerial views, or when a sufficient turbidity gradient is present, waves and glare can occlude views of the subsurface turbulent billows (i.e., see Supporting Information Duguay et al. (2022)). Therefore, unlike KH instabilities, helical cells and episodic pulses, technological limitations and practical constraints have largely limited our understanding of SOVs to that which can be learned from eddy‐resolved numerical modeling.…”

Section: Introductionmentioning

confidence: 99%

“…The SOVs developed as back-toback counter-rotating vortices, one flanking each side of the mixing interface, each rotating in the opposite sense of the other. Recent eddy-resolved modeling has also predicted single-sided SOVs (Duguay et al, 2022) or has failed to detect SOVs entirely (Cheng & Constantinescu, 2020;Guillén Ludeña et al, 2017), suggesting they need not form in the dual back-to-back model discussed by Constantinescu et al (2011), nor are they universal to all confluences. SOVs are thought to arise from a downwelling of superelevated flow mechanism: as the opposing flows collide near the apex, a portion of their kinetic energy is converted to potential energy (i.e., superelevated surface), which subsequently reverts back to kinetic energy as the superelevated mass is accelerated toward the bed (Constantinescu et al, 2011;Horna-Munoz et al, 2020;Sukhodolov & Sukhodolova, 2019).…”

mentioning

confidence: 99%

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Aerial Observations and Numerical Simulations Confirm Density‐Driven Streamwise Vortices at a River Confluence

Duguay

Biron

Lacey

2022

Water Resources Research

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Aerial Observations and Numerical Simulations Confirm Density‐Driven Streamwise Vortices at a River Confluence

Duguay

Biron

Lacey

2022

Water Resources Research

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“…In summary, mesoscale eddies can cause changes in the spatial distribution of ocean elements (such as heat, freshwater, nutrient and chlorophyll concentration) through their motions (horizontal movement, rotation and vertical pumping, Sasai et al, 2010;Kouketsu et al, 2015;Xu et al, 2019;Patel et al, 2020;Geng et al, 2021). In addition, mesoscale eddies also induce heat flux changes at the air-sea interface (Chelton, 2013;Frenger et al, 2013;Ma et al, 2015;Ma et al, 2016), subduction of modal water (Xu et al, 2016;Xu et al, 2014), and enhancement of mixing in the ocean interior (Ma and Wang, 2014b;Qi et al, 2020;Duguay et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Comparative analysis of four types of mesoscale eddies in the Kuroshio-Oyashio extension region

Sun

Liu

et al. 2022

Front. Mar. Sci.

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Oceanic mesoscale cyclonic (anticyclonic) eddies usually have cold (warm) cores and counterclockwise (clockwise) flow fields in the Northern Hemisphere. However, “abnormal” cyclonic (anticyclonic) eddies with warm (cold) cores and counterclockwise (clockwise) flow fields have recently been identified in the Kuroshio-Oyashio Extension (KOE) region. Here, traditional cyclonic cold-core eddies (CCEs) and anticyclonic warm-core eddies (AWEs) are termed normal eddies, and cyclonic warm-core eddies (CWEs) and anticyclonic cold-core eddies (ACEs) are called abnormal eddies. Applying a vector geometry-based automatic eddy detection method to the Ocean General Circulation Model for the Earth Simulator reanalysis data (OFES), a three-dimensional eddy dataset is obtained and used to quantify the statistical characteristics of these eddies. Results illustrate that the number of CCEs, AWEs, CWEs, and ACEs accounted for 38.46, 36.15, 13.40, and 11.99%, respectively. In the vertical direction, normal eddies are concentrated in the upper 2,000 m, while abnormal eddies are mainly found in the upper 600 m of the ocean. On seasonal scales, normal eddies are more abundant in winter and spring than in summer and autumn, with the opposite trend found for abnormal eddies. Potential density changes modulated by normal eddies are dominated by eddies-induced temperature anomalies, while salinity anomalies dominate the changes modulated by abnormal eddies. This study expands the types of eddies and enriches their understanding in the KOE region.

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“…However, WMLES with wall functions fading the role of this requirement by identifying the primary grid point within the log-law region (30 < z+ < 500). Although details of near-bed turbulence are reduced, the wall modelled approach has been widely applied to investigate large-scale turbulent phenomena within the outer region of the water column in flume and fluvial applications [30]. A velocity-based wall function was employed to ascertain the near-wall turbulent viscosity and bed shear stress caused by the rough solid boundary.…”

Section: Wall-modelled Large-eddy (Wmles) Simulationmentioning

confidence: 99%

Numerical Simulation of Confluence Flow in a Degraded Bed Under Different Turbulence Models with a Comparison of Rigid Lid and Volume of Fluid

Behzad

Mohammadian

Rennie

et al. 2022

Preprint

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The fluid dynamics of open channel confluences are highly complex due to the flow separation, mixing and secondary currents. Although numerous studies in the past few decades have focused on the numerical simulation of confluence flow, deformed beds were rarely used. This study attempts to address this issue through numerical simulation of the flow behavior in an open channel confluence flume with an equilibrium degraded bed in OpenFOAM. In the present study, six turbulence models, including Reynolds-Averaged Navier-Stokes (RANS) (standard k–ε, realizable k–ε, k–ω SST, V2-f), large-eddy simulation (LES) and detached eddy simulation (DES) models were performed using rigid lid and volume of fluid (VoF) methods. The accuracy of the models was statistically analyzed by comparing with the observation data, and their performance was prioritized accordingly. The results of this study demonstrated that the LES model had the best performance, with a minimum average normalized mean square error (NRMSE) of 9% under the VoF assumption and 27% under the rigid lid method.

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Large‐scale turbulent mixing at a mesoscale confluence assessed through drone imagery and eddy‐resolved modelling

Cited by 11 publications

References 61 publications

Aerial Observations and Numerical Simulations Confirm Density‐Driven Streamwise Vortices at a River Confluence

Aerial Observations and Numerical Simulations Confirm Density‐Driven Streamwise Vortices at a River Confluence

Comparative analysis of four types of mesoscale eddies in the Kuroshio-Oyashio extension region

Numerical Simulation of Confluence Flow in a Degraded Bed Under Different Turbulence Models with a Comparison of Rigid Lid and Volume of Fluid

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