Numerical Simulations of Air–Sea Interaction under High Wind Conditions Using a Coupled Model: A Study of Hurricane Development

Bao, Jian‐Wen; Wilczak, J. M.; Choi, Jei-Kook; Kantha, Lakshmi

doi:10.1175/1520-0493(2000)128<2190:nsoasi>2.0.co;2

Cited by 208 publications

(137 citation statements)

References 47 publications

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“…With the extreme high winds, intense rainfall, large ocean waves, and copious sea spray the surface flux parameterization should be updated. This is illustrated by numerical simulation of air-sea interaction under high wind conditions using a coupled atmosphere-ocean-wave modeling system (Bao et al 2000). Improvement of WWATCH for high wind conditions needs finer resolution and more realistic parameterization for surface momentum flux.…”

Section: ) Summer Monsoon Season (Cycle 288)mentioning

confidence: 99%

South China Sea Wind-Wave Characteristics. Part I: Validation of Wavewatch-III Using TOPEX/Poseidon Data

Chu

Chen

et al. 2004

Journal of Atmospheric and Oceanic Technology

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A full-spectral third-generation ocean wind-wave model, Wavewatch-III, has been implemented in the South China Sea (SCS) for investigating wind-wave characteristics. This model was developed at the Ocean Modeling Branch of the National Centers for Environmental Prediction (NCEP). The NASA QuickSCAT data (0.25Њ resolution) 2 times daily were used to simulate the wind waves for the entire year of 2000. The significant wave heights from Wavewatch-III are compared to the TOPEX/Poseidon (T/P) significant wave height data over the satellite crossover points in SCS. The model errors of significant wave height have Gaussian-type distribution with a small mean value of 0.02 m (almost no bias). The model errors are comparable to the T/P altimeter accuracy (0.5 m) in the central SCS and are smaller than the T/P altimeter accuracy in the northern and southern SCS, which indicates the capability of Wavewatch-III for SCS wave simulation.

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Section: ) Summer Monsoon Season (Cycle 288)mentioning

confidence: 99%

South China Sea Wind-Wave Characteristics. Part I: Validation of Wavewatch-III Using TOPEX/Poseidon Data

Chu

Chen

et al. 2004

Journal of Atmospheric and Oceanic Technology

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“…Fairall et al (1994) clai- med that, without taking account of evaporating spray droplets or some other source of latent heat, the boundary layer of modeled tropical cyclones would evolve in an unrealistic manner. Kepert et al (1999), Bao et al (2000) and Bao et al (2011) investigated the impact of spray on hurricanes using a coupled atmosphere-ocean-wave model and found that spray increases the air-sea fluxes and hurricane intensity substantially. Sea spray and spume can enhance the air-sea enthalpy exchange (Andreas and Emanuel, 2001) and make the interaction between the sea and air in the surface boundary layer more complex (Doyle, 2002).…”

Section: Introductionmentioning

confidence: 99%

Impacts of sea spray on the boundary layer structure of Typhoon Imbudo

Tang

Chen

et al. 2013

Acta Oceanol. Sin.

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High winds in a typhoon over the ocean can produce substantial amounts of spray in the lower part of the atmospheric boundary layer, which can modify the transfer of momentum, heat, and moisture across the air-sea interface. However, the consequent effects on the boundary layer structure and the evolution of the typhoon are largely unknown. The focus of this paper is on the role of sea spray on the storm intensity and the structure of the atmospheric boundary layer. The case study is Typhoon Imbudo in July 2003. The results show that sea spray tends to intensify storms by increasing the sea surface heat fluxes. Moreover, the effects of sea spray are mainly felt in boundary layer. Spray evaporation causes the atmospheric boundary layer to experience cooling and moistening. Sea spray can cause significant effects on the structure of boundary layer. The boundary-layer height over the eyewall area east to the center of Typhoon Imbudo was increased with a maximum up to about 550 m due to sea spray, which is closely related with the enhancements of the heat fluxes, upward motions, and horizontal winds in this region due to sea spray. Key words: sea spray, typhoon, boundary structure IntroductionTyphoon is one of the most destructive natural disasters affecting China. Each year coastal South China is impacted seriously by typhoons that form over the western Pacific and the South China Sea. Millions of people live along the coastline and are exposed to the threat from wind, rain, storm surges, and severe weather caused by western Pacific typhoons. During the last two decades, the theory of typhoon evolution has been investigated extensively. In particular, large efforts were focused on the effects of large-scale circulation, typhoon structure, and terrain, etc. on the evolution of the typhoon (see the review in Meng et al., 2002). By comparison, the role of air-sea interaction processes in western Pacific typhoons seems to have received less attention in the earlier studies.Indeed, typhoon, one of the most energetic weather events over the ocean, is a powerful engine that runs on the energy extracted from the ocean. The air-sea transfer of momentum and enthalpy has long been recognized as important elements for generating and maintaining hurricanes. Turbulent transfer processes over the ocean are commonly parameterized using Monin-Obukhov similarity theory. However, during high-wind, hurricane conditions, large amounts of sea spray are produced by bursting air bubbles in whitecaps and by tearing spume from the wave crests. Consequently, both turbulence and sea spray provide routes by which moisture, heat, and momentum cross the air-sea interface. Although the question as to whether or how sea spray affects the evolution of hurricanes has

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“…A large number of various hurricane and air-sea interaction models are available in the literature, some including a very detailed and specific description of the influencing factors and realistic regional geographic features, e.g., a large hybrid model of hurricane Opal in the Gulf of Mexico suggested by Bao et al (2000). Yet, the conclusion made by the authors there was that a realistic hurricane evolution could be simulated without a 'physically faithful description of fluxes at the air-sea interface, so long as the amount of momentum and enthalpy fluxes from the model's lower boundary … is sufficient to sustain hurricane evolution'.…”

Section: Introductionmentioning

confidence: 99%

Effect of Ocean Spray on Vertical Momentum Transport Under High-Wind Conditions

Rastigejev

Suslov

Lin

2011

Boundary-Layer Meteorol

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Two mathematical models are proposed detailing the influence of ocean spray on vertical momentum transport under high-wind conditions associated with a hurricane or severe storm. The first model is based on a turbulent kinetic energy (TKE) equation and accounts for the so-called lubrication effect due to the reduction of turbulence intensity. The second model is based on Monin-Obukhov similarity (MOS) and uses available experimental data. It is demonstrated that the flow acceleration is negligible for wind speeds below a certain critical value due to the fact that the spray volume concentration is low for such speeds. For wind speeds higher than the critical value, the spray concentration rapidly increases, which results in significant flow acceleration. Both models produce qualitatively similar results for all turbulent flow parameters considered. It was found that the MOS-based model tends to predict a noticeably stronger lubrication effect than the TKE-based model, especially for lower wind speeds. The results of model calculations are in very good agreement with available experimental data for the spray production values near the upper bound. It is also shown that neither the value of the turbulent Schmidt number in the TKE-based model nor the choice of a stability profile function affects the spray-laden flow dynamics significantly.

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Numerical Simulations of Air–Sea Interaction under High Wind Conditions Using a Coupled Model: A Study of Hurricane Development

Cited by 208 publications

References 47 publications

South China Sea Wind-Wave Characteristics. Part I: Validation of Wavewatch-III Using TOPEX/Poseidon Data

South China Sea Wind-Wave Characteristics. Part I: Validation of Wavewatch-III Using TOPEX/Poseidon Data

Impacts of sea spray on the boundary layer structure of Typhoon Imbudo

Effect of Ocean Spray on Vertical Momentum Transport Under High-Wind Conditions

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