The Application of Infrared Spectral Radiances and Fluxes for Arctic Climate Monitoring and Cloud Phase Determination from Space

The Arctic climate is strongly influenced by infrared (IR) radiation emitted and absorbed by greenhouse gases, clouds, and the surface. As the Arctic continues to rapidly change, it is crucial to further understand how changes in such geophysical variables influence changes in IR flux at the Arctic...

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Bibliographic Details
Main Author:	Peterson, Colten
Other Authors:	Huang, Xianglei, Ivanov, Valeriy Y, Li, Cheng, Ruf, Christopher S
Format:	Thesis
Language:	English
Published:	2022
Subjects:	Arctic Infrared Radiation and Clouds Atmospheric Oceanic and Space Sciences Science Arctic
Online Access:	https://hdl.handle.net/2027.42/174592 https://doi.org/10.7302/6323

id	ftumdeepblue:oai:deepblue.lib.umich.edu:2027.42/174592
record_format	openpolar
spelling	ftumdeepblue:oai:deepblue.lib.umich.edu:2027.42/174592 2024-01-07T09:40:56+01:00 The Application of Infrared Spectral Radiances and Fluxes for Arctic Climate Monitoring and Cloud Phase Determination from Space Peterson, Colten Huang, Xianglei Ivanov, Valeriy Y Li, Cheng Ruf, Christopher S 2022 application/pdf https://hdl.handle.net/2027.42/174592 https://doi.org/10.7302/6323 en_US eng https://hdl.handle.net/2027.42/174592 https://dx.doi.org/10.7302/6323 orcid:0000-0003-4904-9959 Peterson, Colten; 0000-0003-4904-9959 Arctic Infrared Radiation and Clouds Atmospheric Oceanic and Space Sciences Science Thesis 2022 ftumdeepblue https://doi.org/10.7302/6323 2023-12-10T17:53:00Z The Arctic climate is strongly influenced by infrared (IR) radiation emitted and absorbed by greenhouse gases, clouds, and the surface. As the Arctic continues to rapidly change, it is crucial to further understand how changes in such geophysical variables influence changes in IR flux at the Arctic surface and the top-of-atmosphere. Cloud phase (i.e., ice, liquid, and mixed) can affect the clouds’ overall contributions to the IR fluxes. However, the spatial and temporal occurrences of Arctic cloud phase are not well characterized. Satellite observations of spectrally resolved IR fluxes can be used to connect changes in the atmosphere and surface to broadband IR flux changes, however, such studies have not been performed in the Arctic. Spectral IR radiances can be used for satellite-based cloud phase retrievals, but conventional methods using the mid-IR window region (~800-1250 cm-1) have limitations in polar regions, especially for mixed phase clouds. It may be possible to improve Arctic mid-IR cloud phase retrievals with far-IR (<~600 cm-1) measurements. However, few studies have investigated far-IR cloud phase retrievals from space. Overall, this dissertation studies the potential and limitations of spectral mid-IR and far-IR radiances and fluxes for monitoring Arctic IR radiation and identifying cloud phase from space. It contains four studies. The first study examines the trends of zonal mean spectral outgoing longwave radiation (OLR) and greenhouse efficiencies (GHE) in the Arctic from 2003 to 2016 using spectral flux derived from collocated Atmospheric IR Sounder (AIRS) and the Clouds and the Earth's Radiant Energy System observations in conjunction with AIRS retrievals. Positive and negative trends in Arctic OLR and GHE are observed across the far-IR and mid-IR spectral regions, depending on the season, and the largest positive OLR and GHE trends occur in spring. Sensitivity studies reveal that surface temperature increases contribute most to the OLR and GHE trends, but the effects of atmospheric ... Thesis Arctic University of Michigan: Deep Blue Arctic
institution	Open Polar
collection	University of Michigan: Deep Blue
op_collection_id	ftumdeepblue
language	English
topic	Arctic Infrared Radiation and Clouds Atmospheric Oceanic and Space Sciences Science
spellingShingle	Arctic Infrared Radiation and Clouds Atmospheric Oceanic and Space Sciences Science Peterson, Colten The Application of Infrared Spectral Radiances and Fluxes for Arctic Climate Monitoring and Cloud Phase Determination from Space
topic_facet	Arctic Infrared Radiation and Clouds Atmospheric Oceanic and Space Sciences Science
description	The Arctic climate is strongly influenced by infrared (IR) radiation emitted and absorbed by greenhouse gases, clouds, and the surface. As the Arctic continues to rapidly change, it is crucial to further understand how changes in such geophysical variables influence changes in IR flux at the Arctic surface and the top-of-atmosphere. Cloud phase (i.e., ice, liquid, and mixed) can affect the clouds’ overall contributions to the IR fluxes. However, the spatial and temporal occurrences of Arctic cloud phase are not well characterized. Satellite observations of spectrally resolved IR fluxes can be used to connect changes in the atmosphere and surface to broadband IR flux changes, however, such studies have not been performed in the Arctic. Spectral IR radiances can be used for satellite-based cloud phase retrievals, but conventional methods using the mid-IR window region (~800-1250 cm-1) have limitations in polar regions, especially for mixed phase clouds. It may be possible to improve Arctic mid-IR cloud phase retrievals with far-IR (<~600 cm-1) measurements. However, few studies have investigated far-IR cloud phase retrievals from space. Overall, this dissertation studies the potential and limitations of spectral mid-IR and far-IR radiances and fluxes for monitoring Arctic IR radiation and identifying cloud phase from space. It contains four studies. The first study examines the trends of zonal mean spectral outgoing longwave radiation (OLR) and greenhouse efficiencies (GHE) in the Arctic from 2003 to 2016 using spectral flux derived from collocated Atmospheric IR Sounder (AIRS) and the Clouds and the Earth's Radiant Energy System observations in conjunction with AIRS retrievals. Positive and negative trends in Arctic OLR and GHE are observed across the far-IR and mid-IR spectral regions, depending on the season, and the largest positive OLR and GHE trends occur in spring. Sensitivity studies reveal that surface temperature increases contribute most to the OLR and GHE trends, but the effects of atmospheric ...
author2	Huang, Xianglei Ivanov, Valeriy Y Li, Cheng Ruf, Christopher S
format	Thesis
author	Peterson, Colten
author_facet	Peterson, Colten
author_sort	Peterson, Colten
title	The Application of Infrared Spectral Radiances and Fluxes for Arctic Climate Monitoring and Cloud Phase Determination from Space
title_short	The Application of Infrared Spectral Radiances and Fluxes for Arctic Climate Monitoring and Cloud Phase Determination from Space
title_full	The Application of Infrared Spectral Radiances and Fluxes for Arctic Climate Monitoring and Cloud Phase Determination from Space
title_fullStr	The Application of Infrared Spectral Radiances and Fluxes for Arctic Climate Monitoring and Cloud Phase Determination from Space
title_full_unstemmed	The Application of Infrared Spectral Radiances and Fluxes for Arctic Climate Monitoring and Cloud Phase Determination from Space
title_sort	application of infrared spectral radiances and fluxes for arctic climate monitoring and cloud phase determination from space
publishDate	2022
url	https://hdl.handle.net/2027.42/174592 https://doi.org/10.7302/6323
geographic	Arctic
geographic_facet	Arctic
genre	Arctic
genre_facet	Arctic
op_relation	https://hdl.handle.net/2027.42/174592 https://dx.doi.org/10.7302/6323 orcid:0000-0003-4904-9959 Peterson, Colten; 0000-0003-4904-9959
op_doi	https://doi.org/10.7302/6323
_version_	1787421707814830080

The Application of Infrared Spectral Radiances and Fluxes for Arctic Climate Monitoring and Cloud Phase Determination from Space

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