This thesis presents a new method of estimating ocean latent heat flux (LHF) using satellite data. The surface layer equations derived from Monin-Obukhov similarity theory are closed with empirical parameterizations, and patched to a mixed layer model yielding a two-layer PBL model. This is the first proof that such a model can be applied in non-strongly convective situations. Two new retrievals of moisture parameters are derived, one for the surface to 500 meter integrated water vapor {dollar}(Wsb {lcub}B{rcub}){dollar} and one for the mixed-layer humidity {dollar}(qsb{lcub}m{rcub}).{dollar} Inputs include total integrated water vapor retrieved from the Special Sensor Microwave Imager (SSM/I), sea surface temperature optimally interpolated from retrievals from the Advanced Very High Resolution Radiometer and buoy/ship measurements (OI SST), and ECMWF analyzed air-sea temperature difference (T-SST). An analytic relationship between {dollar}Wsb{lcub}B{rcub}{dollar} and near-surface humidity is presented as a replacement for the statistical relationship of Schulz et al. (1993). LHF is then calculated using the new SSM/I-based retrieval of ML-humidity, SSM/I retrieval of wind speed, OI SST, and ECMWF T-SST. Model errors are assessed, and the {dollar}qsb{lcub}m{rcub}{dollar} method derived in this thesis is found to perform the best. Systematic errors are small, and random errors are 26 W/m{dollar}sp2.{dollar} Monthly averages of LHF have been calculated using all available SSM/I data on a 1{dollar}spcirc{dollar} by 1{dollar}spcirc{dollar} grid for 1992-1997. Differences with other published climatologies, both those derived from SSM/I data and from traditional data, have been discussed. Differences between the current work and previous SSM/I methods are evenly split between model parameterization differences and the new moisture retrieval. Errors due to averaging the input variables and due to errors in merchant ship measurements dominate the differences between the current work and traditional climatologies. This analysis establishes the limiting factors in LHF calculation and produces the most accurate LHF climatology to date. It is the first full SSM/I climatology which will be made available to the general scientific community.
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机译:本文提出了一种利用卫星数据估算海洋潜热通量的新方法。从Monin-Obukhov相似性理论得出的表面层方程式通过经验参数化封闭,并修补到混合层模型中,从而得到两层PBL模型。这是此类模型可用于非强对流情况的第一个证明。导出了两种新的湿度参数检索方法,一种是对表面至500米的累积水蒸气{dollar}(Wsb {lcub} B {rcub}){dollar},另一种是对混合层湿度{dollar}(qsb {lcub) } m {rcub})。{dollar}输入包括从特殊传感器微波成像仪(SSM / I)提取的总水汽总量,从超高分辨率高分辨率辐射计和浮标/船舶测量值(OI)提取的最佳海面温度插值SST)和ECMWF分析了气海温差(T-SST)。 {Wsb {lcub} B {rcub}美元和近地表湿度之间的解析关系被提出来代替Schulz等人的统计关系。 (1993)。然后,使用新的基于SSM / I的ML湿度检索,风速的SSM / I检索,OI SST和ECMWF T-SST计算LHF。对模型误差进行了评估,发现本文得出的{qsb {lcub} m {rcub} {dollar}方法表现最佳。系统误差很小,随机误差为26 W / m {dollar} sp2。{dollar} LHF的月平均值已使用1 {dollar} spcirc {dollar}上1 {dollar}上的所有可用SSM / I数据进行了计算。 1992-1997年的spcirc {dollar}网格。讨论了与其他已发布气候的差异,这些差异既来自SSM / I数据,也来自传统数据。当前工作和以前的SSM / I方法之间的差异在模型参数化差异和新的水分取回之间平均分配。平均输入变量和商船测量误差导致的误差主导了当前工作与传统气候之间的差异。该分析确定了LHF计算中的限制因素,并产生了迄今为止最准确的LHF气候。这是将向普通科学界提供的第一个完整的SSM / I气候学。
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