A New Benchmark for Surface Radiation ...
Document type :
Article dans une revue scientifique: Article original
DOI :
Permalink :
Title :
A New Benchmark for Surface Radiation Products over the East Asia-Pacific Region Retrieved from the Himawari-8/AHI Next-Generation Geostationary Satellite
Author(s) :
Letu, Husi [Auteur]
Aerospace Information Research Institute [AIRICAS]
Nakajima, Takashi Y. [Auteur]
Tokai University
Wang, Tianxing [Auteur]
Sun Yat-sen University [Guangzhou] [SYSU]
Shang, Huazhe [Auteur]
Aerospace Information Research Institute [AIRICAS]
Ma, Run [Auteur]
University of Chinese Academy of Sciences [Beijing] [UCAS]
Yang, Kun [Auteur]
Tsinghua University [Beijing] [THU]
Baran, Anthony J. [Auteur]
United Kingdom Met Office [Exeter]
Riedi, Jerome [Auteur]
LOA
interaction Clouds Aerosols Radiations - ICARE/AERIS Data and Services Center - UMS 2877 [ICARE]
Ishimoto, Hiroshi [Auteur]
Meteorological Research Institute [Tsukuba] [MRI]
Yoshida, Mayumi [Auteur]
Japan Aerospace Exploration Agency [Tsukuba] [JAXA]
Shi, Chong [Auteur]
Aerospace Information Research Institute [AIRICAS]
Khatri, Pradeep [Auteur]
Center for Atmospheric and Oceanic Studies [Sendai]
Du, Yihan [Auteur]
Sun Yat-sen University [Guangzhou] [SYSU]
Chen, Liangfu [Auteur]
Aerospace Information Research Institute [AIRICAS]
Shi, Jiancheng [Auteur]
Chinese Academy of Sciences [Beijing] [CAS]
Aerospace Information Research Institute [AIRICAS]
Nakajima, Takashi Y. [Auteur]
Tokai University
Wang, Tianxing [Auteur]
Sun Yat-sen University [Guangzhou] [SYSU]
Shang, Huazhe [Auteur]
Aerospace Information Research Institute [AIRICAS]
Ma, Run [Auteur]
University of Chinese Academy of Sciences [Beijing] [UCAS]
Yang, Kun [Auteur]
Tsinghua University [Beijing] [THU]
Baran, Anthony J. [Auteur]
United Kingdom Met Office [Exeter]
Riedi, Jerome [Auteur]

LOA
interaction Clouds Aerosols Radiations - ICARE/AERIS Data and Services Center - UMS 2877 [ICARE]
Ishimoto, Hiroshi [Auteur]
Meteorological Research Institute [Tsukuba] [MRI]
Yoshida, Mayumi [Auteur]
Japan Aerospace Exploration Agency [Tsukuba] [JAXA]
Shi, Chong [Auteur]
Aerospace Information Research Institute [AIRICAS]
Khatri, Pradeep [Auteur]
Center for Atmospheric and Oceanic Studies [Sendai]
Du, Yihan [Auteur]
Sun Yat-sen University [Guangzhou] [SYSU]
Chen, Liangfu [Auteur]
Aerospace Information Research Institute [AIRICAS]
Shi, Jiancheng [Auteur]
Chinese Academy of Sciences [Beijing] [CAS]
Journal title :
Bulletin of the American Meteorological Society
Abbreviated title :
Bull. Amer. Meteorol. Soc.
Volume number :
103
Pages :
-
Publication date :
2022-06-04
ISSN :
0003-0007
English keyword(s) :
Algorithms
Cloud retrieval
Remote sensing
Cloud retrieval
Remote sensing
HAL domain(s) :
Planète et Univers [physics]/Océan, Atmosphère
English abstract : [en]
Surface downward radiation (SDR), including shortwave downward radiation (SWDR) and longwave downward radiation (LWDR), is of great importance to energy and climate studies. Considering the lack of reliable SDR data with ...
Show more >Surface downward radiation (SDR), including shortwave downward radiation (SWDR) and longwave downward radiation (LWDR), is of great importance to energy and climate studies. Considering the lack of reliable SDR data with a high spatiotemporal resolution in the East Asia–Pacific (EAP) region, we derived SWDR and LWDR at 10-min and 0.05° resolutions for this region from 2016 to 2020 based on the next-generation geostationary satellite Himawari-8 (H-8). The SDR product is unique in terms of its all-sky features, high accuracy, and high-resolution levels. The cloud effect is fully considered in the SDR product, and the influence of high aerosol loadings and topography on the SWDR are considered. Compared to benchmark products of the radiation, such as Clouds and the Earth’s Radiant Energy System (CERES) and the European Centre for Medium-Range Weather Forecasts (ECMWF) next-generation reanalysis (ERA5), and the Global Land Surface Satellite (GLASS), not only is the resolution of the new SDR product notably much higher, but the product accuracy is also higher than that of those products. In particular, hourly and daily root-mean-square errors of the new SWDR are 104.9 and 31.5 W m−2, respectively, which are much smaller than those of CERES (at 121.6 and 38.6 W m−2, respectively), ERA5 (at 176.6 and 39.5 W m−2, respectively), and GLASS (daily of 36.5 W m−2). Meanwhile, RMSEs of hourly and daily values of the new LWDR are 19.6 and 14.4 W m−2, respectively, which are comparable to that of CERES and ERA5, and even better over high-altitude regions.Show less >
Show more >Surface downward radiation (SDR), including shortwave downward radiation (SWDR) and longwave downward radiation (LWDR), is of great importance to energy and climate studies. Considering the lack of reliable SDR data with a high spatiotemporal resolution in the East Asia–Pacific (EAP) region, we derived SWDR and LWDR at 10-min and 0.05° resolutions for this region from 2016 to 2020 based on the next-generation geostationary satellite Himawari-8 (H-8). The SDR product is unique in terms of its all-sky features, high accuracy, and high-resolution levels. The cloud effect is fully considered in the SDR product, and the influence of high aerosol loadings and topography on the SWDR are considered. Compared to benchmark products of the radiation, such as Clouds and the Earth’s Radiant Energy System (CERES) and the European Centre for Medium-Range Weather Forecasts (ECMWF) next-generation reanalysis (ERA5), and the Global Land Surface Satellite (GLASS), not only is the resolution of the new SDR product notably much higher, but the product accuracy is also higher than that of those products. In particular, hourly and daily root-mean-square errors of the new SWDR are 104.9 and 31.5 W m−2, respectively, which are much smaller than those of CERES (at 121.6 and 38.6 W m−2, respectively), ERA5 (at 176.6 and 39.5 W m−2, respectively), and GLASS (daily of 36.5 W m−2). Meanwhile, RMSEs of hourly and daily values of the new LWDR are 19.6 and 14.4 W m−2, respectively, which are comparable to that of CERES and ERA5, and even better over high-altitude regions.Show less >
Language :
Anglais
Audience :
Internationale
Popular science :
Non
Administrative institution(s) :
Université de Lille
CNRS
CNRS
Collections :
Submission date :
2024-01-16T22:44:18Z
2024-02-13T12:18:15Z
2024-02-19T16:20:28Z
2024-02-13T12:18:15Z
2024-02-19T16:20:28Z