A threshold for wind‐wave growth

[1] Measurements in a closed, recirculating wind-wave tank using variable wind speeds showed that wind waves in the gravity-capillary range exhibit a threshold in their growth. Surface wave height variance spectral densities in the wave number domain were measured for gravity-capillary waves using both radar backscatter and a wavelet transform technique applied to a laser probe. The measurements showed that when the wind speed was slowly ramped up, a threshold wind speed or friction velocity was required to produce waves. Turning the wind on suddenly showed that the wind stress did not grow as rapidly as the wind since the surface waves supporting the stress grew relatively slowly. Changing water temperature or current in the water caused a pronounced change in the wind speed threshold but not in the friction velocity threshold. Changes in fetch of as much as a factor of 2 had no discernible effect on the thresholds. The results imply that wind speed, being a condition imposed on the air-water interface, causes wave growth, while friction velocity, being a result of air-water interactions, is closely related to surface roughness, hence radar cross section, and changes during wave growth.

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