The effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observations

The effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observations

<p>Cloud optical properties such as optical thickness along with surface albedo are important inputs for deriving the shortwave radiative effects of clouds from spaceborne remote sensing. Owing to insufficient knowledge about the snow or ice surface in the Arctic, cloud detection and the retri...

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Main Authors: H. Chen, S. Schmidt, M. D. King, G. Wind, A. Bucholtz, E. A. Reid, M. Segal-Rozenhaimer, W. L. Smith, P. C. Taylor, S. Kato, P. Pilewskie
Format: Article
Language:English
Published: Copernicus Publications 2021-04-01
Series:Atmospheric Measurement Techniques
Online Access:https://amt.copernicus.org/articles/14/2673/2021/amt-14-2673-2021.pdf
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author H. Chen
H. Chen
S. Schmidt
S. Schmidt
M. D. King
G. Wind
A. Bucholtz
E. A. Reid
M. Segal-Rozenhaimer
M. Segal-Rozenhaimer
M. Segal-Rozenhaimer
W. L. Smith
P. C. Taylor
S. Kato
P. Pilewskie
P. Pilewskie
spellingShingle H. Chen
H. Chen
S. Schmidt
S. Schmidt
M. D. King
G. Wind
A. Bucholtz
E. A. Reid
M. Segal-Rozenhaimer
M. Segal-Rozenhaimer
M. Segal-Rozenhaimer
W. L. Smith
P. C. Taylor
S. Kato
P. Pilewskie
P. Pilewskie
The effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observations
Atmospheric Measurement Techniques
author_facet H. Chen
H. Chen
S. Schmidt
S. Schmidt
M. D. King
G. Wind
A. Bucholtz
E. A. Reid
M. Segal-Rozenhaimer
M. Segal-Rozenhaimer
M. Segal-Rozenhaimer
W. L. Smith
P. C. Taylor
S. Kato
P. Pilewskie
P. Pilewskie
author_sort H. Chen
title The effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observations
title_short The effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observations
title_full The effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observations
title_fullStr The effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observations
title_full_unstemmed The effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observations
title_sort effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observations
publisher Copernicus Publications
series Atmospheric Measurement Techniques
issn 1867-1381
1867-8548
publishDate 2021-04-01
description <p>Cloud optical properties such as optical thickness along with surface albedo are important inputs for deriving the shortwave radiative effects of clouds from spaceborne remote sensing. Owing to insufficient knowledge about the snow or ice surface in the Arctic, cloud detection and the retrieval products derived from passive remote sensing, such as from the Moderate Resolution Imaging Spectroradiometer (MODIS), are difficult to obtain with adequate accuracy – especially for low-level thin clouds, which are ubiquitous in the Arctic. This study aims at evaluating the spectral and broadband irradiance calculated from MODIS-derived cloud properties in the Arctic using aircraft measurements collected during the Arctic Radiation-IceBridge Sea and Ice Experiment (ARISE), specifically using the upwelling and downwelling shortwave spectral and broadband irradiance measured by the Solar Spectral Flux Radiometer (SSFR) and the BroadBand Radiometer system (BBR). This starts with the derivation of surface albedo from SSFR and BBR, accounting for the heterogeneous surface in the marginal ice zone (MIZ) with aircraft camera imagery, followed by subsequent intercomparisons of irradiance measurements and radiative transfer calculations in the presence of thin clouds. It ends with an attribution of any biases we found to causes, based on the spectral dependence and the variations in the measured and calculated irradiance along the flight track.</p> <p>The spectral surface albedo derived from the airborne radiometers is consistent with prior ground-based and airborne measurements and adequately represents the surface variability for the study region and time period. Somewhat surprisingly, the primary error in MODIS-derived irradiance fields for this study stems from undetected clouds, rather than from the retrieved cloud properties. In our case study, about 27 % of clouds remained undetected, which is attributable to clouds with an optical thickness of less than 0.5.</p> <p>We conclude that passive imagery has the potential to accurately predict shortwave irradiances in the region if the detection of thin clouds is improved. Of at least equal importance, however, is the need for an operational imagery-based surface albedo product for the polar regions that adequately captures its temporal, spatial, and spectral variability to estimate cloud radiative effects from spaceborne remote sensing.</p>
url https://amt.copernicus.org/articles/14/2673/2021/amt-14-2673-2021.pdf
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spelling doaj-818903b1fe724b738bf49cf733a720d52021-04-07T12:55:45ZengCopernicus PublicationsAtmospheric Measurement Techniques1867-13811867-85482021-04-01142673269710.5194/amt-14-2673-2021The effect of low-level thin arctic clouds on shortwave irradiance: evaluation of estimates from spaceborne passive imagery with aircraft observationsH. Chen0H. Chen1S. Schmidt2S. Schmidt3M. D. King4G. Wind5A. Bucholtz6E. A. Reid7M. Segal-Rozenhaimer8M. Segal-Rozenhaimer9M. Segal-Rozenhaimer10W. L. Smith11P. C. Taylor12S. Kato13P. Pilewskie14P. Pilewskie15University of Colorado, Department of Atmospheric and Oceanic Sciences, Boulder, CO, USAUniversity of Colorado, Laboratory for Atmospheric and Space Physics, Boulder, CO, USAUniversity of Colorado, Department of Atmospheric and Oceanic Sciences, Boulder, CO, USAUniversity of Colorado, Laboratory for Atmospheric and Space Physics, Boulder, CO, USAUniversity of Colorado, Laboratory for Atmospheric and Space Physics, Boulder, CO, USAScience Systems and Applications, Inc., Lanham, MD, USANaval Research Lab, Monterey, CA, USANaval Research Lab, Monterey, CA, USABay Area Environmental Research Institute Sonoma, Sonoma, CA, USANASA Ames Research Center, Moffett Field, CA, USADepartment of Geophysics, Porter School of the Environment and Earth Sciences, Tel Aviv University, Tel Aviv, IsraelNASA Langley Research Center, Climate Science Branch, Hampton, VA, USANASA Langley Research Center, Climate Science Branch, Hampton, VA, USANASA Langley Research Center, Climate Science Branch, Hampton, VA, USAUniversity of Colorado, Department of Atmospheric and Oceanic Sciences, Boulder, CO, USAUniversity of Colorado, Laboratory for Atmospheric and Space Physics, Boulder, CO, USA<p>Cloud optical properties such as optical thickness along with surface albedo are important inputs for deriving the shortwave radiative effects of clouds from spaceborne remote sensing. Owing to insufficient knowledge about the snow or ice surface in the Arctic, cloud detection and the retrieval products derived from passive remote sensing, such as from the Moderate Resolution Imaging Spectroradiometer (MODIS), are difficult to obtain with adequate accuracy – especially for low-level thin clouds, which are ubiquitous in the Arctic. This study aims at evaluating the spectral and broadband irradiance calculated from MODIS-derived cloud properties in the Arctic using aircraft measurements collected during the Arctic Radiation-IceBridge Sea and Ice Experiment (ARISE), specifically using the upwelling and downwelling shortwave spectral and broadband irradiance measured by the Solar Spectral Flux Radiometer (SSFR) and the BroadBand Radiometer system (BBR). This starts with the derivation of surface albedo from SSFR and BBR, accounting for the heterogeneous surface in the marginal ice zone (MIZ) with aircraft camera imagery, followed by subsequent intercomparisons of irradiance measurements and radiative transfer calculations in the presence of thin clouds. It ends with an attribution of any biases we found to causes, based on the spectral dependence and the variations in the measured and calculated irradiance along the flight track.</p> <p>The spectral surface albedo derived from the airborne radiometers is consistent with prior ground-based and airborne measurements and adequately represents the surface variability for the study region and time period. Somewhat surprisingly, the primary error in MODIS-derived irradiance fields for this study stems from undetected clouds, rather than from the retrieved cloud properties. In our case study, about 27 % of clouds remained undetected, which is attributable to clouds with an optical thickness of less than 0.5.</p> <p>We conclude that passive imagery has the potential to accurately predict shortwave irradiances in the region if the detection of thin clouds is improved. Of at least equal importance, however, is the need for an operational imagery-based surface albedo product for the polar regions that adequately captures its temporal, spatial, and spectral variability to estimate cloud radiative effects from spaceborne remote sensing.</p>https://amt.copernicus.org/articles/14/2673/2021/amt-14-2673-2021.pdf

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