Transient Simulation of Last Deglaciation with a New Mechanism for Bølling-Allerød Warming

Zhilu Liu(University of Wisconsin–Madison), Bette L. Otto‐Bliesner(NSF National Center for Atmospheric Research), Feng He(University of Wisconsin–Madison), Esther C. Brady(NSF National Center for Atmospheric Research), Robert A. Tomas(NSF National Center for Atmospheric Research), P. U. Clark(Oregon State University), Anders E. Carlson(University of Wisconsin–Madison), Jean Lynch‐Stieglitz(Georgia Institute of Technology), William B Curry(Woods Hole Oceanographic Institution), Edward J. Brook(Oregon State University), Darin J. Erickson(Oak Ridge National Laboratory), Robert Jacob(Argonne National Laboratory), John E. Kutzbach(University of Wisconsin–Madison), Jun Cheng(University of Wisconsin–Madison)
Science
July 16, 2009
10.1126/science.1171041
Cited by 1,248

Abstract

We conducted the first synchronously coupled atmosphere-ocean general circulation model simulation from the Last Glacial Maximum to the Bølling-Allerød (BA) warming. Our model reproduces several major features of the deglacial climate evolution, suggesting a good agreement in climate sensitivity between the model and observations. In particular, our model simulates the abrupt BA warming as a transient response of the Atlantic meridional overturning circulation (AMOC) to a sudden termination of freshwater discharge to the North Atlantic before the BA. In contrast to previous mechanisms that invoke AMOC multiple equilibrium and Southern Hemisphere climate forcing, we propose that the BA transition is caused by the superposition of climatic responses to the transient CO(2) forcing, the AMOC recovery from Heinrich Event 1, and an AMOC overshoot.

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