The reorganized turbulent eddies over ocean surface waves
ID:580 View Protection:ATTENDEE Updated Time:2026-04-02 11:46:32 Hits:120 Invited speech

Start Time:2026-04-27 11:20(Asia/Shanghai)

Duration:10min

Session:S3-11 专题3.11 气候环境与数学 » F21专题3.11 气候环境与数学

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Abstract
The drag coefficient CdN is a key parameter for accurately modelling atmospheric and upper ocean dynamics. However, the scatter of CdN has confused us for several decades. To better understand the mechanism behind the scatter of CdN, the turbulent theory, which considers the momentum flux carried by the eddies that have vertical size sz and horizontal size sx, is used. By adding the wave coherent (WC) stress to the turbulent kinetic energy (TKE) budget, this study models the turbulent eddies reorganized by the waves. The result shows that the reorganized turbulent eddies affect the dimensionless wind gradient, leading to different roughness lengths z0 derived from different levels of wave-affected wind speed and further resulting in the scatter of CdN. Two experiments from a fixed platform located in the South China Sea, one is a regular observation, and the other is outside the periphery of typhoons, demonstrate the above finding. The observation shows that ratios of z0 derived from different levels of wind rely on the proportion of WC stress to total wind stress, and the horizontal integral length scales of eddies are stretched while the vertical sizes of eddies are shrunk. This study indicates that, to reduce the scatter of CdN, the wave-affected wind should be considered.
 
Keywords
surface wave,marine atmospheric boundary layer;,turbulence;,momentum flux
Speaker
邹仲水
中山大学

Submission Author
邹仲水 中山大学
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Important Date
  • Conference Date

    Apr 25

    2026

    to

    Apr 29

    2026

  • Apr 07 2026

    Draft paper submission deadline

  • Jun 17 2026

    Registration deadline

Sponsored By
未来大气科学论坛理事会
Organized By
河海大学海洋学院
南京大学南京赫尔辛基大气与地球系统科学学院
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