Regional imprints of millennial variability during the MIS 3 period around Antarctica

The climate of the last glacial Marine Isotopic Stage 3 (MIS3) period is characterized by strong millennialscale variability with a succession of DansgaardeOeschger events first identified in Greenland ice cores and associated with variations of the Atlantic Meridional Overturning Circulation (AMOC)...

Full description

Bibliographic Details
Published in:Quaternary Science Reviews
Main Authors: Buiron D., J. Chappellaz, A. Landais, M. Baumgartner, M. Bonazza, E. Capron, M. Frezzotti, M. Kageyama, B. Lemieux Dudon, V. Masson Delmotte, F. Parrenin, A. Schilt, E. Selmo, M. Severi, D. Swingedouw, R. Udisti, STENNI, Barbara
Other Authors: Buiron, D., Stenni, Barbara, J., Chappellaz, A., Landai, M., Baumgartner, M., Bonazza, E., Capron, M., Frezzotti, M., Kageyama, B., Lemieux Dudon, V., Masson Delmotte, F., Parrenin, A., Schilt, E., Selmo, M., Severi, D., Swingedouw, R., Udisti
Format: Article in Journal/Newspaper
Language:English
Published: 2012
Subjects:
Paleoclimate
millennial-scale variability
glacial period
ice core
Talos Dome
global coupled model simulations
Antarctic
Southern Ocean
Greenland
Pacific
Indian
Antarc*
Antarctica
Greenland ice cores
North Atlantic
Online Access:http://hdl.handle.net/10278/42764
https://doi.org/10.1016/j.quascirev.2012.05.023
Description
Summary:The climate of the last glacial Marine Isotopic Stage 3 (MIS3) period is characterized by strong millennialscale variability with a succession of DansgaardeOeschger events first identified in Greenland ice cores and associated with variations of the Atlantic Meridional Overturning Circulation (AMOC). These abrupt events have a smooth and lagged counterpart in water stable isotopes from Antarctic ice cores. In this study we aim at depicting and understanding the circum-Antarctic expression of this millennial-scale variability. To illustrate the mechanisms potentially at work in the response of the southern high latitudes to an abrupt decrease of the AMOC, we first present results from experiments performed with the IPSL-CM4 atmosphere-ocean coupled model under glacial boundary conditions. When the AMOC is perturbed by imposing an additional freshwater flux in the North Atlantic, our model produces the classical bipolar seesaw mechanism generally invoked to explain the warming of the Southern Ocean/Antarctic region. However, this mechanism can be locally offset by faster atmospheric teleconnections originating from the tropics, even though the precise location of this fast response is not coherent among different climate models. Our model results are confronted with a synthesis of Antarctic records of ice core stable isotope and sea-salt sodium, including new data obtained on the TALDICE ice core. The IPSLCM4 produces a dipole-like pattern around Antarctica, with warming in the Atlantic/Indian sectors contrasting with an unexpected cooling in the East-Pacific sector. The latter signal is not detected in our data synthesis. Both ice core data and simulations are consistent in depicting a more rapid response of the Atlantic sector compared to the Indian sector. This feature can be explained by the gradual impact of ocean transport on which faster atmospheric teleconnections are superimposed. Detailed investigations of the sequence of events between different proxies are conducted in three ice cores. Earlier shifts ...

Similar Items