Abstract
<p>Perhaps the most important feedback to orbital climate change is CO<sub>2</sub> storage in the deep ocean.  By regulating atmospheric CO<sub>2</sub>, ocean carbon storage synchronizes glacial climate in both hemispheres, and drives the full magnitude of glacial-interglacial climate change.  However few data exist that directly track the deep ocean’s carbon chemistry over a glacial cycle.  Here, we present geochemical reconstructions of deep ocean circulation, redox, and carbon chemistry from sediment cores making up a detailed depth profile in the South Atlantic, alongside a record of Southern Ocean surface water CO<sub>2</sub>, spanning the last glacial cycle.  These data indicate that initial glacial CO<sub>2</sub> drawdown is associated with a major increase in surface ocean pH in the Antarctic Zone of the Southern Ocean, cooling at depth, enhanced deep ocean stratification, and carbon storage.  Deep ocean carbon storage and deep stratification are further enhanced when CO<sub>2</sub> falls at the onset of Marine Isotope Stage 4, and are also pronounced during the LGM, illustrating a link between orbital scale climate stages and deep ocean carbon.  However our data also illustrate non-linear feedbacks to orbital forcing during glacial terminations, which show abrupt decreases in pH in Southern Ocean surface and subsurface waters, as CO<sub>2</sub> is rapidly expelled from the deep ocean at the end of the last ice age.</p>
Published Version
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