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Title
Japanese: 
English:Representing Cloud Water Content of Extensive Cloud Systems Over Land Using Satellite‐Based Passive Microwave Observations With a Coupled Land and Atmosphere Assimilation Method 
Author
Japanese: 瀬戸里枝, 小池 俊雄, 鼎信次郎.  
English: Rie Seto, Toshio Koike, Shinjiro Kanae.  
Language English 
Journal/Book name
Japanese: 
English:Journal of Geophisical Research : Atmospheres 
Volume, Number, Page        
Published date Dec. 13, 2018 
Publisher
Japanese: 
English:American Geophysical Union 
Conference name
Japanese: 
English: 
Conference site
Japanese: 
English: 
Official URL https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2018JD028864
 
DOI https://doi.org/10.1029/2018JD028864
Abstract We proposed a method to estimate cloud water content (CWC) over land using satellite‐based passive microwave brightness temperatures (TBs) at multiple‐kilometer resolutions with land and atmosphere assimilation to overcome the challenges associated with estimating the CWC of broad cloud systems over land. This method enables estimation of broad cloud systems over land using multifrequency TBs, which have different sensitivities to land and cloud, by concurrently optimizing land emissions and CWC estimates from models. Estimated CWC was validated using vertical two‐dimensional CloudSat products (2B‐CWC‐RVOD and 2C‐ICE). The results were in good accordance with 2B‐CWC‐RVOD in terms of cloud water path and the vertical distribution of CWC but represented underestimates in comparison to 2C‐ICE. We performed sensitivity analysis of CWC estimates of TBs and cloud top height. The results suggested that the error in TBs is not large uncertainty, and that cloud top height affects the estimated CWC more sensitively than TBs. The addition of cloud top height information, as determined from CloudSat products as a constraint of optimization, allows further improvement of the vertical distributions of CWC in case studies. Sensitivity analysis indicated that it is effective to utilize cloud top height data from other satellites, such as next‐generation geostationary meteorological satellites, within an error of about ±600 m for further development of our method. This study revealed that the proposed method has great potential to provide unprecedented data for cloud water path and CWC that are continuously distributed over land and ocean with adequate accuracy.

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