The Momentum Flux Balance at the Sea Surface

Today, second- and third-generation wave models are used for many applications around the world. From the design of coastal structures to proper regional sediment management and from estimates of mixing in the upper ocean to the efficient routing of ships across oceans, the accuracy of these models...

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Bibliographic Details
Main Authors: Resio, Donald, Long, Charles
Other Authors: ENGINEER RESEARCH AND DEVELOPMENT CENTER VICKSBURG MS COASTAL AND HYDRAULICSLAB
Format: Text
Language:English
Published: 2002
Subjects:
Meteorology
Physical and Dynamic Oceanography
Fluid Mechanics
*OCEAN WAVES
*SHALLOW WATER
*WIND VELOCITY
*HYDRODYNAMICS
*DEEP WATER
*LAKE WAVES
MATHEMATICAL MODELS
OCEAN SURFACE
FLUX(RATE)
DISSIPATION
EQUILIBRIUM(GENERAL)
COMPUTATIONAL FLUID DYNAMICS
ATLANTIC OCEAN
SPECTRUM ANALYSIS
MARINE METEOROLOGY
OPEN WATER
MARINE GEOPHYSICS
BERING SEA
*WAVE MODELS
*WAVE GENERATION
WAVE WAVE INTERACTIONS
WIND WAVE SPECTRA
SPECTRAL ANALYSIS
WIND GENERATED WAVES
ENERGY FLUX
SPECTRAL DENSITY
Bering Sea
Deep Water Lake
Lake George
Online Access:http://www.dtic.mil/docs/citations/ADA423553
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA423553
Description
Summary:Today, second- and third-generation wave models are used for many applications around the world. From the design of coastal structures to proper regional sediment management and from estimates of mixing in the upper ocean to the efficient routing of ships across oceans, the accuracy of these models has critical importance. However, following the development of the WAM model in the mid- to late 1980s, there has been little effort focused directly on wave model development. Instead, most research in this area has involved re-calibrating various source terms to obtain better fits to observations (satellite and in situ). Two likely reasons for the lack of focus in this area are (1) the general acceptance outside of the wave community that the WAM model physics provided a good "detailed balance" description of the wave generation process, and (2) wave researchers cannot agree on necessary modifications to the WAM physics. The purpose of this paper is to revisit the general framework of the physics of wave generation and attempt to formulate a concept for wave generation that seems to fit some important constraints implicit in observations over a wide range of generation scales (time and space). Toward this end, data from three very different sites will be used: (1) Lake George - a small, shallow site located in Southeast Australia; (2) FRF Gage #630 - a coastal site located in the Atlantic Ocean in a depth of about 18 meters of water approximately 5 km off the coast of Duck, North Carolina; and (3) NDBC Buoy 46035 - an open ocean site located in deep water in the Bering Sea. These sites cover a wide range of practical wave generation scales, from shallow to deep and from very small fetch to extremely large fetch. (7 figures, 8 refs.)

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