Collaborative Research: Characterizing the Roles of Atmospheric Structure and Clouds on the Radiation and Precipitation Budgets at Summit, Greenland

Funds are provided to characterize the interactions among the atmospheric state, cloud properties, radiation, and precipitation at Summit, Greenland. The objective is to investigate a number of important cloud-related processes, how these interact with the Arctic climate system, and their impact on...

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Bibliographic Details
Main Author: Matthew Shupe
Format: Dataset
Language:unknown
Published: Arctic Data Center 2016
Subjects:
Arctic
Greenland
Ice Sheet
Sea ice
Online Access:https://search.dataone.org/view/urn:uuid:2441757f-3372-4f35-b66f-21c47acc326f
id dataone:urn:uuid:2441757f-3372-4f35-b66f-21c47acc326f
record_format openpolar
spelling dataone:urn:uuid:2441757f-3372-4f35-b66f-21c47acc326f 2024-06-03T18:46:30+00:00 Collaborative Research: Characterizing the Roles of Atmospheric Structure and Clouds on the Radiation and Precipitation Budgets at Summit, Greenland Matthew Shupe Summit, Greenland ENVELOPE(38.4417,38.4417,72.5956,72.5956) BEGINDATE: 2013-10-01T00:00:00Z ENDDATE: 2017-09-30T00:00:00Z 2016-10-14T00:00:00Z https://search.dataone.org/view/urn:uuid:2441757f-3372-4f35-b66f-21c47acc326f unknown Arctic Data Center Dataset 2016 dataone:urn:node:ARCTIC 2024-06-03T18:11:09Z Funds are provided to characterize the interactions among the atmospheric state, cloud properties, radiation, and precipitation at Summit, Greenland. The objective is to investigate a number of important cloud-related processes, how these interact with the Arctic climate system, and their impact on the surface energy and mass budgets. Specific foci will include: 1) Low-cloud persistence mechanisms that lead to long-lived Arctic stratiform clouds, which interact strongly with the atmospheric structure and surface energy budget; 2) Cloud-phase partitioning, which determines the cloud microphysical composition and, ultimately, the effects that clouds have on atmospheric radiation and the hydrologic cycle; and 3) Precipitation partitioning, in order to understand the different modes of precipitation at Summit and how these impact the total surface accumulation. To address these topics, this project will utilize detailed observations from a suite of ground-based remote sensors deployed at Summit as part of the NSF/AON-funded ICECAPS project in combination with data from satellite-borne active remote sensors. High-resolution numerical modeling will also be used to investigate many of the fine-scale cloud processes and their mesoscale influences. These studies over the Greenland Ice Sheet will also be considered within the context of similar measurements and model studies made at other Arctic locations in order to understand these important processes over Summit and, in a more general sense, across the Arctic. Atmospheric water vapor, clouds, and precipitation greatly affect the surface energy and cryospheric mass balances in the Arctic, and are responsible for much of the variability in these balances. It is thought that recent rapid melting of Arctic sea ice may be driven, in part, by changes in cloud cover and radiation. Cloud-related processes and feedbacks are known to be one of the greatest sources of uncertainty in global climate models, and these shortcomings have been clearly identified in model simulations over the Arctic. Thus, the results of this project should improve our understanding of Arctic cloud processes and their inclusion in climate models, which, in turn, will improve predictability. As broader impacts of this research, the project will provide important data analysis and integration experience for four new graduate students at the participating universities. In addition, data and results from this study will be integrated into undergraduate coursework and summer workshops for high school students and teachers. Dataset Arctic Greenland Ice Sheet Sea ice Arctic Data Center (via DataONE) Arctic Greenland ENVELOPE(38.4417,38.4417,72.5956,72.5956)
institution Open Polar
collection Arctic Data Center (via DataONE)
op_collection_id dataone:urn:node:ARCTIC
language unknown
description Funds are provided to characterize the interactions among the atmospheric state, cloud properties, radiation, and precipitation at Summit, Greenland. The objective is to investigate a number of important cloud-related processes, how these interact with the Arctic climate system, and their impact on the surface energy and mass budgets. Specific foci will include: 1) Low-cloud persistence mechanisms that lead to long-lived Arctic stratiform clouds, which interact strongly with the atmospheric structure and surface energy budget; 2) Cloud-phase partitioning, which determines the cloud microphysical composition and, ultimately, the effects that clouds have on atmospheric radiation and the hydrologic cycle; and 3) Precipitation partitioning, in order to understand the different modes of precipitation at Summit and how these impact the total surface accumulation. To address these topics, this project will utilize detailed observations from a suite of ground-based remote sensors deployed at Summit as part of the NSF/AON-funded ICECAPS project in combination with data from satellite-borne active remote sensors. High-resolution numerical modeling will also be used to investigate many of the fine-scale cloud processes and their mesoscale influences. These studies over the Greenland Ice Sheet will also be considered within the context of similar measurements and model studies made at other Arctic locations in order to understand these important processes over Summit and, in a more general sense, across the Arctic. Atmospheric water vapor, clouds, and precipitation greatly affect the surface energy and cryospheric mass balances in the Arctic, and are responsible for much of the variability in these balances. It is thought that recent rapid melting of Arctic sea ice may be driven, in part, by changes in cloud cover and radiation. Cloud-related processes and feedbacks are known to be one of the greatest sources of uncertainty in global climate models, and these shortcomings have been clearly identified in model simulations over the Arctic. Thus, the results of this project should improve our understanding of Arctic cloud processes and their inclusion in climate models, which, in turn, will improve predictability. As broader impacts of this research, the project will provide important data analysis and integration experience for four new graduate students at the participating universities. In addition, data and results from this study will be integrated into undergraduate coursework and summer workshops for high school students and teachers.
format Dataset
author Matthew Shupe
spellingShingle Matthew Shupe
Collaborative Research: Characterizing the Roles of Atmospheric Structure and Clouds on the Radiation and Precipitation Budgets at Summit, Greenland
author_facet Matthew Shupe
author_sort Matthew Shupe
title Collaborative Research: Characterizing the Roles of Atmospheric Structure and Clouds on the Radiation and Precipitation Budgets at Summit, Greenland
title_short Collaborative Research: Characterizing the Roles of Atmospheric Structure and Clouds on the Radiation and Precipitation Budgets at Summit, Greenland
title_full Collaborative Research: Characterizing the Roles of Atmospheric Structure and Clouds on the Radiation and Precipitation Budgets at Summit, Greenland
title_fullStr Collaborative Research: Characterizing the Roles of Atmospheric Structure and Clouds on the Radiation and Precipitation Budgets at Summit, Greenland
title_full_unstemmed Collaborative Research: Characterizing the Roles of Atmospheric Structure and Clouds on the Radiation and Precipitation Budgets at Summit, Greenland
title_sort collaborative research: characterizing the roles of atmospheric structure and clouds on the radiation and precipitation budgets at summit, greenland
publisher Arctic Data Center
publishDate 2016
url https://search.dataone.org/view/urn:uuid:2441757f-3372-4f35-b66f-21c47acc326f
op_coverage Summit, Greenland
ENVELOPE(38.4417,38.4417,72.5956,72.5956)
BEGINDATE: 2013-10-01T00:00:00Z ENDDATE: 2017-09-30T00:00:00Z
long_lat ENVELOPE(38.4417,38.4417,72.5956,72.5956)
geographic Arctic
Greenland
geographic_facet Arctic
Greenland
genre Arctic
Greenland
Ice Sheet
Sea ice
genre_facet Arctic
Greenland
Ice Sheet
Sea ice
_version_ 1800866945427308544

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