Impact of regionally increased CO2 concentrations in coupled climate simulations

In which direction is the influence larger: from the Arctic to the mid-latitudes or vice versa? To answer this question, CO2 concentrations have been regionally increased in different latitudinal belts, namely in the Arctic, in the northern mid-latitudes, everywhere outside of the Arctic and globall...

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Main Authors: Semmler, Tido, Pithan, Felix, Jung, Thomas
Format: Article in Journal/Newspaper
Language:English
Published: Zenodo 2019
Subjects:
Arctic Amplification
Arctic mid-latitude linkages
regional greenhouse gas forcing
energy transport
coupled climate model simulations
Arctic
Greenland
Iceland
Sea ice
Online Access:https://doi.org/10.5281/zenodo.3565412
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author Semmler, Tido
Pithan, Felix
Jung, Thomas
author_facet Semmler, Tido
Pithan, Felix
Jung, Thomas
author_sort Semmler, Tido
collection Zenodo
description In which direction is the influence larger: from the Arctic to the mid-latitudes or vice versa? To answer this question, CO2 concentrations have been regionally increased in different latitudinal belts, namely in the Arctic, in the northern mid-latitudes, everywhere outside of the Arctic and globally, in a series of 150 year coupled model experiments with the AWI Climate Model. This method is applied to allow a decomposition of the response to increasing CO2 concentrations in different regions. It turns out that CO2 increase applied in the Arctic only is very efficient in heating the Arctic and that the energy largely remains in the Arctic. In the first 30 years after switching on the CO2 forcing some robust atmospheric circulation changes, which are associated with the surface temperature anomalies including local cooling of up to 1°C in parts of North America, are simulated. The synoptic activity is decreased in the mid-latitudes. Further into the simulation, surface temperature and atmospheric circulation anomalies become less robust. When quadrupling the CO2 concentration south of 60°N, the March Arctic sea ice volume is reduced by about two thirds in the 150 years of simulation time. When quadrupling the CO2 concentration between 30 and 60°N, the March Arctic sea ice volume is reduced by around one third, the same amount as if quadrupling CO2 north of 60°N. Both atmospheric and oceanic northward energy transport across 60°N are enhanced by up to 0.1 PW and 0.03 PW, respectively, and winter synoptic activity is increased over the Greenland, Norwegian, Iceland (GIN) seas. To a lesser extent the same happens when the CO2 concentration between 30 and 60°N is only increased to 1.65 times the reference value in order to consider the different size of the forcing areas. The increased northward energy transport, leads to Arctic sea ice reduction, and consequently Arctic amplification is present without Arctic CO2 forcing in all seasons but summer, independent of where the forcing is applied south of 60°N. South of ...
format Article in Journal/Newspaper
genre Arctic
Greenland
Iceland
Sea ice
genre_facet Arctic
Greenland
Iceland
Sea ice
geographic Arctic
Greenland
geographic_facet Arctic
Greenland
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institution Open Polar
language English
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https://doi.org/10.5281/zenodo.3565412
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op_rights info:eu-repo/semantics/openAccess
Creative Commons Attribution 4.0 International
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spelling ftzenodo:oai:zenodo.org:3565412 2025-01-16T20:02:51+00:00 Impact of regionally increased CO2 concentrations in coupled climate simulations Semmler, Tido Pithan, Felix Jung, Thomas 2019-12-06 https://doi.org/10.5281/zenodo.3565412 eng eng Zenodo https://zenodo.org/communities/eu https://doi.org/10.5281/zenodo.3565411 https://doi.org/10.5281/zenodo.3565412 oai:zenodo.org:3565412 info:eu-repo/semantics/openAccess Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode Arctic Amplification Arctic mid-latitude linkages regional greenhouse gas forcing energy transport coupled climate model simulations info:eu-repo/semantics/article 2019 ftzenodo https://doi.org/10.5281/zenodo.356541210.5281/zenodo.3565411 2024-12-06T04:01:41Z In which direction is the influence larger: from the Arctic to the mid-latitudes or vice versa? To answer this question, CO2 concentrations have been regionally increased in different latitudinal belts, namely in the Arctic, in the northern mid-latitudes, everywhere outside of the Arctic and globally, in a series of 150 year coupled model experiments with the AWI Climate Model. This method is applied to allow a decomposition of the response to increasing CO2 concentrations in different regions. It turns out that CO2 increase applied in the Arctic only is very efficient in heating the Arctic and that the energy largely remains in the Arctic. In the first 30 years after switching on the CO2 forcing some robust atmospheric circulation changes, which are associated with the surface temperature anomalies including local cooling of up to 1°C in parts of North America, are simulated. The synoptic activity is decreased in the mid-latitudes. Further into the simulation, surface temperature and atmospheric circulation anomalies become less robust. When quadrupling the CO2 concentration south of 60°N, the March Arctic sea ice volume is reduced by about two thirds in the 150 years of simulation time. When quadrupling the CO2 concentration between 30 and 60°N, the March Arctic sea ice volume is reduced by around one third, the same amount as if quadrupling CO2 north of 60°N. Both atmospheric and oceanic northward energy transport across 60°N are enhanced by up to 0.1 PW and 0.03 PW, respectively, and winter synoptic activity is increased over the Greenland, Norwegian, Iceland (GIN) seas. To a lesser extent the same happens when the CO2 concentration between 30 and 60°N is only increased to 1.65 times the reference value in order to consider the different size of the forcing areas. The increased northward energy transport, leads to Arctic sea ice reduction, and consequently Arctic amplification is present without Arctic CO2 forcing in all seasons but summer, independent of where the forcing is applied south of 60°N. South of ... Article in Journal/Newspaper Arctic Greenland Iceland Sea ice Zenodo Arctic Greenland
spellingShingle Arctic Amplification
Arctic mid-latitude linkages
regional greenhouse gas forcing
energy transport
coupled climate model simulations
Semmler, Tido
Pithan, Felix
Jung, Thomas
Impact of regionally increased CO2 concentrations in coupled climate simulations
title Impact of regionally increased CO2 concentrations in coupled climate simulations
title_full Impact of regionally increased CO2 concentrations in coupled climate simulations
title_fullStr Impact of regionally increased CO2 concentrations in coupled climate simulations
title_full_unstemmed Impact of regionally increased CO2 concentrations in coupled climate simulations
title_short Impact of regionally increased CO2 concentrations in coupled climate simulations
title_sort impact of regionally increased co2 concentrations in coupled climate simulations
topic Arctic Amplification
Arctic mid-latitude linkages
regional greenhouse gas forcing
energy transport
coupled climate model simulations
topic_facet Arctic Amplification
Arctic mid-latitude linkages
regional greenhouse gas forcing
energy transport
coupled climate model simulations
url https://doi.org/10.5281/zenodo.3565412

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