Deviation of Wind Stress From Wind Direction Under Low Wind Conditions

The deviation of the wind stress vector from the wind direction at the air‐sea interface under low wind conditions was investigated based on direct eddy covariance flux measurements taken at a coastal tower in the northern South China Sea. The wind stress deviates significantly from the mean wind di...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2018-12, Vol.123 (12), p.9357-9368
Main Authors: Chen, Sheng, Qiao, Fangli, Huang, Chuan Jiang, Zhao, Biao
Format: Article
Language:English
Subjects:
Air flow
Atmosphere
Atmospheric models
Boundary layers
Climate models
Climate prediction
Covariance
Deviation
Drag coefficient
Drag coefficients
Eddy covariance
Geophysics
Height
Low Wind Speeds
Meteorologi
Meteorology
Momentum
Momentum transfer
Nonstationarity
Ocean models
Ocean swell
Ocean waves
Oceans
Removal
Sea surface
Stress
Stress Offwind Angle
Swell
Swells
Temperature (air-sea)
Vectors
Vertical velocities
Vertical velocity spectra
Weather
Weather conditions
Wind
Wind direction
Wind speed
Wind Stress
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Summary:The deviation of the wind stress vector from the wind direction at the air‐sea interface under low wind conditions was investigated based on direct eddy covariance flux measurements taken at a coastal tower in the northern South China Sea. The wind stress deviates significantly from the mean wind direction under low wind conditions, with the deviation angle sometimes exceeding 90°, indicating upward momentum transfer from the ocean to the atmosphere. Negative downwind drag coefficient values begin to occur at a wind speed of approximately 4 m/s. Our results show that ocean swells and nonstationary airflow play critical roles in wind stress. Prominent peaks at the dominant swell frequency in the vertical velocity spectra are observed at a height of 17 m over the mean sea surface, implying that swell‐induced perturbations can reach a height of at least 17 m, and the wave boundary layer can extend more than 10 m above the sea surface. The results of our analysis indicate that at the observation height, the influence of nonstationarity in the wind field is more significant than that of swell‐induced motions on the deviation of wind stress. After the removal of nonstationary motions, the deviation angles of the wind stress from the wind direction are generally reduced and vary substantially at low wind speeds. Plain Language Summary Under calm weather conditions, the wind and stress vectors are not aligned. Therefore, the deviation of the wind stress from the wind direction at the air‐sea interface under low wind conditions was studied. At low wind speeds, the wind stress vector significantly deviated from the wind direction, with deviations that sometimes exceeded 90°, indicating upward momentum transfer from the ocean to the atmosphere, and the wave boundary layer can extend more than 17 m above the sea surface. Ocean swells and nonstationary motions in the wind field may cause the above phenomena. Understanding wind stress characteristics is important for developing ocean, wave, and climate models to improve ocean and climate predictions. Key Points The wind stress vector deviates significantly from the mean wind direction, sometimes exceeding 90 degrees, under light wind conditions Swell‐induced perturbations can reach a height of 17 m above the sea surface under light winds and strong swells The effect of nonstationarity on the stress vector is greater than that of swell‐induced perturbations at a height of nearly 20 m
ISSN:2169-9275
2169-9291
2169-9291
DOI:10.1029/2018JC014137