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Orbital Forcing, Ice Volume, and CO 2 Across the Oligocene‐Miocene Transition
Author(s) -
Greenop Rosanna,
Sosdian Sindia M.,
Henehan Michael J.,
Wilson Paul A.,
Lear Caroline H.,
Foster Gavin L.
Publication year - 2019
Publication title -
paleoceanography and paleoclimatology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.927
H-Index - 127
eISSN - 2572-4525
pISSN - 2572-4517
DOI - 10.1029/2018pa003420
Subject(s) - deglaciation , orbital forcing , glacial period , geology , ice sheet , paleoclimatology , paleontology , antarctic ice sheet , forcing (mathematics) , climatology , climate change , cryosphere , geomorphology , oceanography , sea ice
Abstract Paleoclimate records suggest that a rapid major transient Antarctic glaciation occurred across the Oligocene‐Miocene transition (OMT; ca. 23 Ma; ~50‐m sea level equivalent in 200–300 kyr). Orbital forcing has long been cited as an important factor determining the timing of the OMT glacial event. A similar orbital configuration occurred 1.2 Myr prior to the OMT, however, and was not associated with a major climate event, suggesting that additional mechanisms play an important role in ice sheet growth and decay. To improve our understanding of the OMT, we present a boron isotope‐based CO 2 record between 22 and 24 Ma. This new record shows that δ 11 B/CO 2 was comparatively stable in the million years prior to the OMT glaciation and decreased by 0.7‰ (equivalent to a CO 2 increase of ~65 ppm) over ~300 kyr during the subsequent deglaciation. More data are needed, but we propose that the OMT glaciation was triggered by the same forces that initiated sustained Antarctic glaciation at the Eocene‐Oligocene transition: long‐term decline in CO 2 to a critical threshold and a superimposed orbital configuration favorable to glaciation (an eccentricity minimum and low‐amplitude obliquity change). When comparing the reconstructed CO 2 increase with estimates of δ 18 O sw during the deglaciation phase of the OMT, we find that the sensitivity of the cryosphere to CO 2 forcing is consistent with recent ice sheet modeling studies that incorporate retreat into subglacial basins via ice cliff collapse with modest CO 2 increase, with clear implications for future sea level rise.

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