Bipolar impact and phasing of Heinrich-type climate variability
Martin, K.C.; Buizert, C.; Edwards, J.S.; Kalk, M.L.; Riddell-Young, B.; Brook, E.J.; Beaudette, R.; Severinghaus, J.P.; Sowers, T.A. (2023). Bipolar impact and phasing of Heinrich-type climate variability. Nature (Lond.) 617(7959): 100-104. https://dx.doi.org/10.1038/s41586-023-05875-2
In: Nature: International Weekly Journal of Science. Nature Publishing Group: London. ISSN 0028-0836; e-ISSN 1476-4687, more
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| Authors | | Top |
- Martin, K.C.
- Buizert, C.
- Edwards, J.S.
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- Kalk, M.L.
- Riddell-Young, B.
- Brook, E.J.
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- Beaudette, R.
- Severinghaus, J.P.
- Sowers, T.A.
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| Abstract |
During the last ice age, the Laurentide Ice Sheet exhibited extreme iceberg discharge events that are recorded in North Atlantic sediments. These Heinrich events have far-reaching climate impacts, including widespread disruptions to hydrological and biogeochemical cycles. They occurred during Heinrich stadials—cold periods with strongly weakened Atlantic overturning circulation. Heinrich-type variability is not distinctive in Greenland water isotope ratios, a well-dated site temperature proxy, complicating efforts to assess their regional climate impact and phasing against Antarctic climate change. Here we show that Heinrich events have no detectable temperature impact on Greenland and cooling occurs at the onset of several Heinrich stadials, and that both types of Heinrich variability have a distinct imprint on Antarctic climate. Antarctic ice cores show accelerated warming that is synchronous with increases in methane during Heinrich events, suggesting an atmospheric teleconnection, despite the absence of a Greenland climate signal. Greenland ice-core nitrogen stable isotope ratios, a sensitive temperature proxy, indicate an abrupt cooling of about three degrees Celsius at the onset of Heinrich Stadial 1 (17.8 thousand years before present, where present is defined as 1950). Antarctic warming lags this cooling by 133 ± 93 years, consistent with an oceanic teleconnection. Paradoxically, proximal sites are less affected by Heinrich events than remote sites, suggesting spatially complex event dynamics. |
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