Increasing Resolution and Resolving Convection Improve the Simulation of Cloud-Radiative Effects Over the North Atlantic

Clouds interact with atmospheric radiation and substantially modify the Earth's energy budget. Cloud formation processes occur over a vast range of spatial and temporal scales, which make their thorough numerical representation challenging. Therefore, the impact of parameter choices for simulat...

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Main Authors:	Senf, Fabian, Voigt, Aiko, Clerbaux, Nicolas, Hünerbein, Anja, Deneke, Hartwig
Format:	Article in Journal/Newspaper
Language:	English
Published:	Hoboken, NJ : Wiley 2020
Subjects:	Bias Decomposition Cloud Classification Cloud-Radiative Effects High-Resolution Simulations Meteosat Observations TOA Energy Budget 550 North Atlantic
Online Access:	https://oa.tib.eu/renate/handle/123456789/7276 https://doi.org/10.34657/6323

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spelling	ftleibnizopen:oai:oai.leibnizopen.de:--9q6YoBg80Wlv18KW8k 2023-10-29T02:38:21+01:00 Increasing Resolution and Resolving Convection Improve the Simulation of Cloud-Radiative Effects Over the North Atlantic Senf, Fabian Voigt, Aiko Clerbaux, Nicolas Hünerbein, Anja Deneke, Hartwig 2020 application/pdf https://oa.tib.eu/renate/handle/123456789/7276 https://doi.org/10.34657/6323 eng eng Hoboken, NJ : Wiley CC BY 4.0 Unported https://creativecommons.org/licenses/by/4.0/ JGR : Atmospheres 125 (2020), Nr. 19 Bias Decomposition Cloud Classification Cloud-Radiative Effects High-Resolution Simulations Meteosat Observations TOA Energy Budget 550 article Text 2020 ftleibnizopen https://doi.org/10.34657/6323 2023-10-01T23:11:28Z Clouds interact with atmospheric radiation and substantially modify the Earth's energy budget. Cloud formation processes occur over a vast range of spatial and temporal scales, which make their thorough numerical representation challenging. Therefore, the impact of parameter choices for simulations of cloud-radiative effects is assessed in the current study. Numerical experiments are carried out using the ICOsahedral Nonhydrostatic (ICON) model with varying grid spacings between 2.5 and 80 km and with different subgrid-scale parameterization approaches. Simulations are performed over the North Atlantic with either one-moment or two-moment microphysics and with convection being parameterized or explicitly resolved by grid-scale dynamics. Simulated cloud-radiative effects are compared to products derived from Meteosat measurements. Furthermore, a sophisticated cloud classification algorithm is applied to understand the differences and dependencies of simulated and observed cloud-radiative effects. The cloud classification algorithm developed for the satellite observations is also applied to the simulation output based on synthetic infrared brightness temperatures, a novel approach that is not impacted by changing insolation and guarantees a consistent and fair comparison. It is found that flux biases originate equally from clear-sky and cloudy parts of the radiation field. Simulated cloud amounts and cloud-radiative effects are dominated by marine, shallow clouds, and their behavior is highly resolution dependent. Bias compensation between shortwave and longwave flux biases, seen in the coarser simulations, is significantly diminished for higher resolutions. Based on the analysis results, it is argued that cloud-microphysical and cloud-radiative properties have to be adjusted to further improve agreement with observed cloud-radiative effects. © 2020. The Authors. publishedVersion Article in Journal/Newspaper North Atlantic LeibnizOpen (The Leibniz Association)
institution	Open Polar
collection	LeibnizOpen (The Leibniz Association)
op_collection_id	ftleibnizopen
language	English
topic	Bias Decomposition Cloud Classification Cloud-Radiative Effects High-Resolution Simulations Meteosat Observations TOA Energy Budget 550
spellingShingle	Bias Decomposition Cloud Classification Cloud-Radiative Effects High-Resolution Simulations Meteosat Observations TOA Energy Budget 550 Senf, Fabian Voigt, Aiko Clerbaux, Nicolas Hünerbein, Anja Deneke, Hartwig Increasing Resolution and Resolving Convection Improve the Simulation of Cloud-Radiative Effects Over the North Atlantic
topic_facet	Bias Decomposition Cloud Classification Cloud-Radiative Effects High-Resolution Simulations Meteosat Observations TOA Energy Budget 550
description	Clouds interact with atmospheric radiation and substantially modify the Earth's energy budget. Cloud formation processes occur over a vast range of spatial and temporal scales, which make their thorough numerical representation challenging. Therefore, the impact of parameter choices for simulations of cloud-radiative effects is assessed in the current study. Numerical experiments are carried out using the ICOsahedral Nonhydrostatic (ICON) model with varying grid spacings between 2.5 and 80 km and with different subgrid-scale parameterization approaches. Simulations are performed over the North Atlantic with either one-moment or two-moment microphysics and with convection being parameterized or explicitly resolved by grid-scale dynamics. Simulated cloud-radiative effects are compared to products derived from Meteosat measurements. Furthermore, a sophisticated cloud classification algorithm is applied to understand the differences and dependencies of simulated and observed cloud-radiative effects. The cloud classification algorithm developed for the satellite observations is also applied to the simulation output based on synthetic infrared brightness temperatures, a novel approach that is not impacted by changing insolation and guarantees a consistent and fair comparison. It is found that flux biases originate equally from clear-sky and cloudy parts of the radiation field. Simulated cloud amounts and cloud-radiative effects are dominated by marine, shallow clouds, and their behavior is highly resolution dependent. Bias compensation between shortwave and longwave flux biases, seen in the coarser simulations, is significantly diminished for higher resolutions. Based on the analysis results, it is argued that cloud-microphysical and cloud-radiative properties have to be adjusted to further improve agreement with observed cloud-radiative effects. © 2020. The Authors. publishedVersion
format	Article in Journal/Newspaper
author	Senf, Fabian Voigt, Aiko Clerbaux, Nicolas Hünerbein, Anja Deneke, Hartwig
author_facet	Senf, Fabian Voigt, Aiko Clerbaux, Nicolas Hünerbein, Anja Deneke, Hartwig
author_sort	Senf, Fabian
title	Increasing Resolution and Resolving Convection Improve the Simulation of Cloud-Radiative Effects Over the North Atlantic
title_short	Increasing Resolution and Resolving Convection Improve the Simulation of Cloud-Radiative Effects Over the North Atlantic
title_full	Increasing Resolution and Resolving Convection Improve the Simulation of Cloud-Radiative Effects Over the North Atlantic
title_fullStr	Increasing Resolution and Resolving Convection Improve the Simulation of Cloud-Radiative Effects Over the North Atlantic
title_full_unstemmed	Increasing Resolution and Resolving Convection Improve the Simulation of Cloud-Radiative Effects Over the North Atlantic
title_sort	increasing resolution and resolving convection improve the simulation of cloud-radiative effects over the north atlantic
publisher	Hoboken, NJ : Wiley
publishDate	2020
url	https://oa.tib.eu/renate/handle/123456789/7276 https://doi.org/10.34657/6323
genre	North Atlantic
genre_facet	North Atlantic
op_source	JGR : Atmospheres 125 (2020), Nr. 19
op_rights	CC BY 4.0 Unported https://creativecommons.org/licenses/by/4.0/
op_doi	https://doi.org/10.34657/6323
_version_	1781064281208389632

Increasing Resolution and Resolving Convection Improve the Simulation of Cloud-Radiative Effects Over the North Atlantic

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