Modelling interglacial climate response to insolation and CO2 during the past 800,000 years

The climate of nine interglacials of the past 800,000 years has been simulated with both snapshot and transient experiments using the model LOVECLIM. These simulations allow to investigate the relative contributions of insolation and CO2 to the intensity and duration of each interglacial as well as...

Full description

Bibliographic Details
Main Authors:	Yin, Qiuzhen, Berger, Andre, The 2017 Joint IAPSO-IAMAS-IAGA Assembly
Other Authors:	UCL - SST/ELI/ELIC - Earth & Climate
Format:	Conference Object
Language:	Ndonga
Published:	2017
Subjects:	Sea ice
Online Access:	http://hdl.handle.net/2078.1/186235

id	ftunivlouvain:oai:dial.uclouvain.be:boreal:186235
record_format	openpolar
spelling	ftunivlouvain:oai:dial.uclouvain.be:boreal:186235 2024-05-19T07:48:20+00:00 Modelling interglacial climate response to insolation and CO2 during the past 800,000 years Yin, Qiuzhen Berger, Andre The 2017 Joint IAPSO-IAMAS-IAGA Assembly UCL - SST/ELI/ELIC - Earth & Climate 2017 http://hdl.handle.net/2078.1/186235 ng ndo boreal:186235 http://hdl.handle.net/2078.1/186235 info:eu-repo/semantics/conferenceObject 2017 ftunivlouvain 2024-04-24T01:19:36Z The climate of nine interglacials of the past 800,000 years has been simulated with both snapshot and transient experiments using the model LOVECLIM. These simulations allow to investigate the relative contributions of insolation and CO2 to the intensity and duration of each interglacial as well as the differences between the interglacials at global and regional scales. The transient simulations which cover a full range of precession, obliquity and eccentricity allow to investigate the response of different climate variables at different latitudes to these three astronomical parameters. The results show that the relative contribution of insolation and CO2 on the warmth intensity varies from one interglacial to another. They also show that CO2 plays a dominant role on the variations of the global annual mean temperature and the southern high latitude temperature and sea ice, whereas, insolation plays a dominant role on the variations of monsoon precipitation, vegetation and of the northern high latitude temperature and sea ice. The results also show that, compared to today, the past interglacials are warmer during boreal summer and cooler during boreal winter leading to a warmer annual mean with varying length for different interglacials. The warm interval of MIS-11 is the longest, confirming its long duration as found in proxy records. The long duration of MIS-11 is related to a particular combination of eccentricity, obliquity and precession as well as to a high CO2 concentration. Through the comparison with other interglacials, unique features in precession and obliquity as well as in regional climate response are found in MIS-5e and MIS-11, which might help to understand why they appear as the two warmest interglacials during the past 800ka. The transient simulations allow also to look for past interglacial analogues for our present interglacial and its natural future. The differences between the simulated seasonal behaviour of the past interglacials highlight the importance of seasonal climate reconstruction ... Conference Object Sea ice DIAL@UCLouvain (Université catholique de Louvain)
institution	Open Polar
collection	DIAL@UCLouvain (Université catholique de Louvain)
op_collection_id	ftunivlouvain
language	Ndonga
description	The climate of nine interglacials of the past 800,000 years has been simulated with both snapshot and transient experiments using the model LOVECLIM. These simulations allow to investigate the relative contributions of insolation and CO2 to the intensity and duration of each interglacial as well as the differences between the interglacials at global and regional scales. The transient simulations which cover a full range of precession, obliquity and eccentricity allow to investigate the response of different climate variables at different latitudes to these three astronomical parameters. The results show that the relative contribution of insolation and CO2 on the warmth intensity varies from one interglacial to another. They also show that CO2 plays a dominant role on the variations of the global annual mean temperature and the southern high latitude temperature and sea ice, whereas, insolation plays a dominant role on the variations of monsoon precipitation, vegetation and of the northern high latitude temperature and sea ice. The results also show that, compared to today, the past interglacials are warmer during boreal summer and cooler during boreal winter leading to a warmer annual mean with varying length for different interglacials. The warm interval of MIS-11 is the longest, confirming its long duration as found in proxy records. The long duration of MIS-11 is related to a particular combination of eccentricity, obliquity and precession as well as to a high CO2 concentration. Through the comparison with other interglacials, unique features in precession and obliquity as well as in regional climate response are found in MIS-5e and MIS-11, which might help to understand why they appear as the two warmest interglacials during the past 800ka. The transient simulations allow also to look for past interglacial analogues for our present interglacial and its natural future. The differences between the simulated seasonal behaviour of the past interglacials highlight the importance of seasonal climate reconstruction ...
author2	UCL - SST/ELI/ELIC - Earth & Climate
format	Conference Object
author	Yin, Qiuzhen Berger, Andre The 2017 Joint IAPSO-IAMAS-IAGA Assembly
spellingShingle	Yin, Qiuzhen Berger, Andre The 2017 Joint IAPSO-IAMAS-IAGA Assembly Modelling interglacial climate response to insolation and CO2 during the past 800,000 years
author_facet	Yin, Qiuzhen Berger, Andre The 2017 Joint IAPSO-IAMAS-IAGA Assembly
author_sort	Yin, Qiuzhen
title	Modelling interglacial climate response to insolation and CO2 during the past 800,000 years
title_short	Modelling interglacial climate response to insolation and CO2 during the past 800,000 years
title_full	Modelling interglacial climate response to insolation and CO2 during the past 800,000 years
title_fullStr	Modelling interglacial climate response to insolation and CO2 during the past 800,000 years
title_full_unstemmed	Modelling interglacial climate response to insolation and CO2 during the past 800,000 years
title_sort	modelling interglacial climate response to insolation and co2 during the past 800,000 years
publishDate	2017
url	http://hdl.handle.net/2078.1/186235
genre	Sea ice
genre_facet	Sea ice
op_relation	boreal:186235 http://hdl.handle.net/2078.1/186235
_version_	1799466548083032064

Modelling interglacial climate response to insolation and CO2 during the past 800,000 years

Similar Items