基本信息
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个人简介
Fields of Interest
Aerosols; radiation; data assimilation; satellite remote sensing; global modeling; mesoscale modeling
Description of Scientific Projects
A number of naturally occurring and anthropogenic aerosol particles affect atmospheric composition and energy balances globally. The academic community and other agencies and countries are interested in aerosol particles because of their potential climatic implications. As a result, aerosol particles are receiving more attention than ever before. This includes international aerosol field programs, the development of aerosol retrieval algorithms for existing satellites, and the deployment of several new satellite sensors designed specifically for aerosol detection. In response to this interest, the Naval Research Laboratory has developed a multi-component global aerosol simulation capability called NAAPS (the NRL Aerosol Analysis and Prediction System) and embedded a similar capability directly into the NRL Coupled Ocean/Atmosphere Mesoscale Prediction System (COAMPS®). NRL research efforts combine satellite data streams, model simulations, and other available data through data assimilation systems to produce observational and model datasets at regional and global scale for model initialization and studies of direct and indirect aerosol forcing. Data received and processed daily at NRL include NPP VIIRS, CALIPSO, MODIS, MISR, GOES, MTSAT, AVHRR, and surface weather observations. NRL also receives six-day global weather forecasts and three-day triply nested mesoscale weather forecasts for multiple regions of the world. This unique combination of daily satellite data and global and regional weather forecasting allow us to develop NAAPS and COAMPS® into one of the most complete real-time aerosol simulations in the world. The scientific challenges facing simulation of atmospheric aerosols include quantification of satellite-retrieved aerosols; developing methods for characterizing source regions and source strength; efficient treatment of microphysics, chemistry, and optical properties; applying data assimilation and ensemble techniques to aerosol data streams; and allowing two-way interaction between the global and regional models. NAAPS and COAMPS® are validated and improved through the collection and use of field data, including that collected on ships and aircraft. Model development is closely tied to involvement in international field experiments in which we participate through measurements and modeling.
Aerosols; radiation; data assimilation; satellite remote sensing; global modeling; mesoscale modeling
Description of Scientific Projects
A number of naturally occurring and anthropogenic aerosol particles affect atmospheric composition and energy balances globally. The academic community and other agencies and countries are interested in aerosol particles because of their potential climatic implications. As a result, aerosol particles are receiving more attention than ever before. This includes international aerosol field programs, the development of aerosol retrieval algorithms for existing satellites, and the deployment of several new satellite sensors designed specifically for aerosol detection. In response to this interest, the Naval Research Laboratory has developed a multi-component global aerosol simulation capability called NAAPS (the NRL Aerosol Analysis and Prediction System) and embedded a similar capability directly into the NRL Coupled Ocean/Atmosphere Mesoscale Prediction System (COAMPS®). NRL research efforts combine satellite data streams, model simulations, and other available data through data assimilation systems to produce observational and model datasets at regional and global scale for model initialization and studies of direct and indirect aerosol forcing. Data received and processed daily at NRL include NPP VIIRS, CALIPSO, MODIS, MISR, GOES, MTSAT, AVHRR, and surface weather observations. NRL also receives six-day global weather forecasts and three-day triply nested mesoscale weather forecasts for multiple regions of the world. This unique combination of daily satellite data and global and regional weather forecasting allow us to develop NAAPS and COAMPS® into one of the most complete real-time aerosol simulations in the world. The scientific challenges facing simulation of atmospheric aerosols include quantification of satellite-retrieved aerosols; developing methods for characterizing source regions and source strength; efficient treatment of microphysics, chemistry, and optical properties; applying data assimilation and ensemble techniques to aerosol data streams; and allowing two-way interaction between the global and regional models. NAAPS and COAMPS® are validated and improved through the collection and use of field data, including that collected on ships and aircraft. Model development is closely tied to involvement in international field experiments in which we participate through measurements and modeling.
研究兴趣
论文共 133 篇作者统计合作学者相似作者
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JOURNAL OF GEOPHYSICAL RESEARCH-ATMOSPHERESno. 18 (2023)
Melinda T. T. Berman,Xinxin Ye,Laura H. H. Thapa,David A. A. Peterson,Edward J. J. Hyer,Amber J. J. Soja,Emily M. M. Gargulinski,Ivan Csiszar,Christopher C. C. Schmidt, Pablo E. E. Saide
INTERNATIONAL JOURNAL OF WILDLAND FIREno. 5 (2023): 665-678
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ATMOSPHERIC CHEMISTRY AND PHYSICSno. 15 (2022): 9949-9967
user-61447a76e55422cecdaf7d19(2022)
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ATMOSPHERIC CHEMISTRY AND PHYSICSno. 15 (2022): 9915-9947
Peng Xian,Jianglong Zhang,Travis D. Toth,Blake Sorenson,Peter R. Colarco,Zak Kipling, N. T. O'Neill,Edward J. Hyer, James R. Campell,Jeffrey S. Reid, K. Ranjbar
Atmospheric Chemistry and Physicspp.1-63, (2021)
Peng Xian,Jianglong Zhang,Travis D. Toth,Blake Sorenson,Peter R. Colarco,Zak Kipling, Norm T. O'Neill,Edward J. Hyer, James R. Campell,Jeffrey S. Reid,Keyvan Ranjbar
semanticscholar(2021)
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