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Climate Sensitivity on Geological Timescales Controlled by Nonlinear Feedbacks and Ocean Circulation
Author(s) -
Farnsworth A.,
Lunt D. J.,
O'Brien C. L.,
Foster G. L.,
Inglis G. N.,
Markwick P.,
Pancost R. D.,
Robinson S. A.
Publication year - 2019
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1029/2019gl083574
Subject(s) - climate sensitivity , climatology , climate change , climate model , context (archaeology) , climate state , environmental science , ocean current , albedo (alchemy) , forcing (mathematics) , solar constant , general circulation model , sensitivity (control systems) , global warming , geology , atmospheric sciences , effects of global warming , oceanography , solar irradiance , art , paleontology , electronic engineering , performance art , engineering , art history
Climate sensitivity is a key metric used to assess the magnitude of global warming given increased CO 2 concentrations. The geological past can provide insights into climate sensitivity; however, on timescales of millions of years, factors other than CO 2 can drive climate, including paleogeographic forcing and solar luminosity. Here, through an ensemble of climate model simulations covering the period 150–35 million years ago, we show that climate sensitivity to CO 2 doubling varies between ∼3.5 and 5.5 °C through this time. These variations can be explained as a nonlinear response to solar luminosity, evolving surface albedo due to changes in ocean area, and changes in ocean circulation. The work shows that the modern climate sensitivity is relatively low in the context of the geological record, as a result of relatively weak feedbacks due to a relatively low CO 2 baseline, and the presence of ice and relatively small ocean area in the modern continental configuration.