Surface waves and currents in aquatic vegetation

McWilliams, James C.

doi:10.1017/jfm.2023.50

Cited by 1 publication

(2 citation statements)

References 32 publications

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“…It is also consistent with the omission of the wave orbital velocity in (2.5), neglecting the interaction between wave and canopy drag (Yan et al. 2021; McWilliams 2023). A more detailed description of macroalgal farm configurations will be presented in § 2.3.…”

Section: Methodssupporting

confidence: 77%

“…This assumption is supported by the analyses in Yan et al (2021), which examined a set of dimensionless parameters including the Cauchy number and buoyancy number. It is also consistent with the omission of the wave orbital velocity in (2.5), neglecting the interaction between wave and canopy drag (Yan et al 2021;McWilliams 2023). A more detailed description of macroalgal farm configurations will be presented in § 2.3.…”

Section: Model Descriptionsupporting

confidence: 61%

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Langmuir turbulence in suspended kelp farms

Bo,

McWilliams,

Yan

et al. 2024

J. Fluid Mech.

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This study investigates the influence of suspended kelp farms on ocean mixed layer hydrodynamics in the presence of currents and waves. We use the large eddy simulation method, where the wave effect is incorporated by solving the wave-averaged equations. Distinct Langmuir circulation patterns are generated within various suspended farm configurations, including horizontally uniform kelp blocks and spaced kelp rows. Intensified turbulence arises from the farm-generated Langmuir circulation, as opposed to the standard Langmuir turbulence observed without a farm. The creation of Langmuir circulation within the farm is attributed to two primary factors depending on farm configuration: (i) enhanced vertical shear due to kelp frond area density variability, and (ii) enhanced lateral shear due to canopy discontinuity at lateral edges of spaced rows. Both enhanced vertical and lateral shear of streamwise velocity, representing the lateral and vertical vorticity components, respectively, can be tilted into downstream vorticity to create Langmuir circulation. This vorticity tilting is driven by the Craik–Leibovich vortex force associated with the Stokes drift of surface gravity waves. In addition to the farm-generated Langmuir turbulence, canopy shear layer turbulence is created at the farm bottom edge due to drag discontinuity. The intensity of different types of turbulence depends on both kelp frond area density and the geometric configuration of the farm. The farm-generated turbulence has substantial consequences for nutrient supply and kelp growth. These findings also underscore the significance of the presence of obstacle structures in modifying ocean mixed layer characteristics.

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Section: Methodssupporting

confidence: 77%