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1. Polydisperse Sea Spray Effect on the Vertical Momentum Transport in Hurricanes

   https://doi.org/10.1175/JAS-D-23-0195.1  

   Rastigejev, Yevgenii; Suslov, Sergey_A (July 2024, Journal of the Atmospheric Sciences)

   Abstract This study focuses on the influence of the sea spray polydispersity on the vertical transport of momentum in a turbulent marine atmospheric boundary layer in high-wind conditions of a hurricane. The Eulerian multifluid model treating air and spray droplets of different sizes as interacting interpenetrating continua is developed and its numerical solutions are analyzed. Several droplet size distribution spectra and correlation laws relating wind speed and spray production intensity are considered. Polydisperse model solutions have confirmed the difference between the roles small and large spray droplets play in modifying the turbulent momentum transport that have been previously identified by monodisperse spray models. The obtained results have also provided a physical explanation for the previously unreported phenomenon of the formation of thin low-eddy-viscosity “sliding” layers in strongly turbulent boundary layer flows laden with predominantly fine spray. Significance StatementAchieving better accuracy in hurricane forecasts requires an in-depth understanding and accurate modeling of the ocean spray effect on the vertical fluxes of momentum and heat in a hurricane boundary layer. It has been shown that this effect depends on the size distribution of spray droplets, also known as spray polydispersity. This study aims to investigate the influence of a polydisperse spray on the vertical momentum transport within hurricane boundary layers by employing a modern theory of turbulent disperse multiphase flows. 

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2. Impacts of Terrain Slope and Surface Roughness Variations on Turbulence Generation in the Nighttime Stable Boundary Layer

   https://doi.org/10.1029/2024JD041815  

   Sun, Jielun; Bhimireddy, Sudheer_R; Kristovich, David_A_R; Wang, Junming; Hiscox, April_L; Mahrt, Larry; Petty, Grant_W (March 2025, Journal of Geophysical Research: Atmospheres)

   Abstract Terrain slopes with and without upslope large surface roughness impact downstream shear‐generated turbulence differently in the nighttime stable boundary layer (SBL). These differences can be identified through variations in the relationship between turbulence and wind speed at a given height, known as the HOckey STick (HOST) transition, as compared to the HOST relationship over flat terrain. The transport of cold surface air from elevated uniform terrain reduces downstream air temperature not much air stratification. As terrain slope rises, the increasing cold and heavy air enhances downstream hydrostatic imbalance, resulting in increasing turbulence for a given wind speed. That is, the rate of turbulence increase with wind speed from downslope flow is independent of terrain slope. Upslope large surface roughness elements enhance vertical turbulent mixing, elevating cold surface air from the terrain. Horizontal transport of this elevated, cold, turbulent air layer reduces the downstream upper warm air temperature. Benefiting from the progressive reduction of downstream stable stratification with increasing height in the SBL, wind shear can effectively generate strong turbulence. In addition to the turbulence enhancement from the cold downslope flow, the rate of turbulence increase with wind speed is elevated. This study demonstrates key physical mechanisms for turbulence generation captured by the HOST relationship. It also highlights the influence of terrain features on these mechanisms through deviations from the HOST relationship over flat terrain. 

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3. The Parameter Dependence of Eddy Heat Flux in a Homogeneous Quasigeostrophic Two-Layer Model on a β Plane with Quadratic Friction

   https://doi.org/10.1175/JAS-D-20-0145.1  

   Chang, Chiung-Yin; Held, Isaac M. (January 2021, Journal of the Atmospheric Sciences)

   null (Ed.)

   Abstract This study investigates the parameter dependence of eddy heat flux in a homogeneous quasigeostrophic two-layer model on a β plane with imposed environmental vertical wind shear and quadratic frictional drag. We examine the extent to which the results can be explained by a recently proposed diffusivity theory for passive tracers in two-dimensional turbulence. To account for the differences between two-layer and two-dimensional models, we modify the two-dimensional theory according to our two-layer f -plane analyses reported in an earlier study. Specifically, we replace the classic Kolmogorovian spectral slope, −5/3, assumed to predict eddy kinetic energy spectrum in the former with a larger slope, −7/3, suggested by a heuristic argument and fit to the model results in the latter. It is found that the modified theory provides a reasonable estimate within the regime where both and the strength of the frictional drag, , are much smaller than unity (here, c D is the nondimensional drag coefficient divided by the depth of the layer, k d is the wavenumber of deformation radius, and U is the imposed background vertical wind shear). For values of and that are closer to one, the theory works only if the full spectrum shape of the eddy kinetic energy is given. Despite the qualitative, fitting nature of this approach and its failure to explain the full parameter range, we believe its documentation here remains useful as a reference for the future attempt in pursuing a better theory. 

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4. Turbulent Transport of Spray Droplets in the Vicinity of Moving Surface Waves

   https://doi.org/10.1175/JPO-D-19-0003.1  

   Richter, David H.; Dempsey, Anne E.; Sullivan, Peter P. (July 2019, Journal of Physical Oceanography)

   A common technique for estimating the sea surface generation functions of spray and aerosols is the so-called flux–profile method, where fixed-height concentration measurements are used to infer fluxes at the surface by assuming a form of the concentration profile. At its simplest, this method assumes a balance between spray emission and deposition, and under these conditions the concentration profile follows a power-law shape. It is the purpose of this work to evaluate the influence of waves on this power-law theory, as well as investigate its applicability over a range of droplet sizes. Large-eddy simulations combined with Lagrangian droplet tracking are used to resolve the turbulent transport of spray droplets over moving, monochromatic waves at the lower surface. The wave age and the droplet diameter are varied, and it is found that droplets are highly influenced both by their inertia (i.e., their inability to travel exactly with fluid streamlines) and the wave-induced turbulence. Deviations of the vertical concentration profiles from the power-law theory are found at all wave ages and for large droplets. The dynamics of droplets within the wave boundary layer alter their net vertical fluxes, and as a result, estimates of surface emission based on the flux–profile method can yield significant errors. In practice, the resulting implication is that the flux–profile method may unsuitable for large droplets, and the combined effect of inertia and wave-induced turbulence is responsible for the continued spread in their surface source estimates. 

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5. Elevated Momentum Flux in the Surfzone during a Storm

   https://doi.org/10.1175/JAS-D-24-0090.1  

   Potter, Henry; Lyu, Meng; Yang, Xin (July 2025, Journal of the Atmospheric Sciences)

   Abstract Drag coefficient parameterizations, which are largely developed from homogenous deep ocean data, are ineffective nearshore where conditions are nonuniform. This is problematic because operational forecast accuracy depends upon reliable quantification of air–sea momentum transfer. This is especially important for storms which threaten coastal life and property. To help fill this knowledge gap, direct flux measurements were collected from the beach and pierhead in Duck, North Carolina, as part of the During Nearshore Event Experiment (DUNEX). The footprint analysis shows these fluxes were sourced in the surfzone and offshore, representing very different conditions. During a weeklong storm, wind speeds and significant wave heights were 20 m s⁻¹and 4 m, leading to a broad, vigorous surfzone. The drag coefficient in the surfzone was twice the offshore value, explained by increased roughness due to wind stress and bathymetric changes. The Charnock parameter is well predicted by wave age, but it is expected this is site-specific due to unique bathymetry. A horizontal wind speed gradient was observed and attributed to the high surfzone roughness. The wavelengths of the turbulent eddies in the surfzone were smaller than offshore or predicted by universal scaling. This research offers novel insights that can contribute to a crucial collective effort to develop robust coastal flux models, leading to improved forecasting. Significance StatementWhen wind blows over the ocean, the energy associated with its motion is moved from the air into water. This energy transfer helps grow waves and drive currents which, via many pathways, alter the characteristics of the upper ocean and lower atmosphere. In turn, this affects weather and climate, so it is critical this energy exchange is accounted for in forecasts. Energy transfer is reasonably well understood in the deep ocean, but not nearshore where conditions are nonuniform and change quickly, especially in storms where very few measurements are made. To remedy this, data were collected in May 2022 during a storm in Duck, North Carolina, which had wind speeds of 20 m s⁻¹and 4-m wave heights. The extreme conditions created a very wide and energetic surfzone. Wind measurements were made on the beach and approximately 500 m offshore. Due to the rough surface, twice the energy was transferred from the air into the ocean in the surfzone than offshore and the wind speed decreased as it crossed the surfzone. Finally, the wavelengths of the wind that transfer energy into the ocean are much smaller than offshore or predicted by previous research. 

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