The drag coefficient parameterization of wind stress is investigated for tropical storm conditions using model sensitivity studies. The Massachusetts Institute of Technology (MIT) Ocean General Circulation Model was run in a regional setting with realistic stratification and forcing fields representing Hurricane Frances, which in early September 2004 passed east of the Caribbean Leeward Island chain. The model was forced with a NOAA-HWIND wind speed product after converting it to wind stress using four different drag coefficient parameterizations. Respective model results were tested against in situ measurements of temperature profiles and velocity, available from an array of 22 surface drifters and 12 subsurface floats. Changing the drag coefficient parameterization from one that saturated at a value of 2.3 × 10 -3 to a constant drag coefficient of 1.2 × 10-3 reduced the standard deviation difference between the simulated minus the measured sea surface temperature change from 0.8°C to 0.3°C. Additionally, the standard deviation in the difference between simulated minus measured high pass filtered 15-m current speed reduced from 15 cm/s to 5 cm/s. The maximum difference in sea surface temperature response when two different turbulent mixing parameterizations were implemented was 0.3°C, i.e., only 11% of the maximum change of sea surface temperature caused by the storm. Copyright 2009 by the American Geophysical Union.
展开▼
机译:使用模型敏感性研究研究了热带风暴条件下风应力的阻力系数参数化。麻省理工学院(MIT)海洋总体环流模型在具有现实分层和强迫场的区域环境中运行,代表着飓风弗朗西斯,该飓风于2004年9月上旬从加勒比背风群岛链条通过。使用四个不同的阻力系数参数化将模型转换为风应力后,使用NOAA-HWIND风速乘积强制模型。针对温度分布和速度的原位测量测试了相应的模型结果,这些测量结果可从22个表面浮标和12个地下浮标中获得。将阻力系数参数化从饱和值2.3×10 -3更改为恒定阻力系数1.2×10-3,可将模拟值减去测得的海表温度变化之间的标准差从0.8°C减小至0.3 ℃。此外,模拟负测量高通滤波15 m电流速度之间的差的标准偏差从15 cm / s减小到5 cm / s。实施两种不同的湍流混合参数设置时,海面温度响应的最大差异为0.3°C,即仅为风暴引起的海面温度最大变化的11%。美国地球物理联盟版权所有2009。
展开▼
