Bipolar seesaw control on last interglacial sea level

TitleBipolar seesaw control on last interglacial sea level
Publication TypeUnpublished
Year of Publication2015
AuthorsMarino, G, Rohling, E, Rodríguez-Sanz, L, Grant, KM, Heslop, D, Roberts, AP, Stanford, JD, Yu, J
Series TitleNature
Date PublishedJune

Our current understanding of ocean?atmosphere?cryosphere interactions at ice-age terminations relies largely on assessments of the most recent (last) glacial?interglacial transition1, 2, 3, Termination I (T-I). But the extent to which T-I is representative of previous terminations remains unclear. Testing the consistency of termination processes requires comparison of time series of critical climate parameters with detailed absolute and relative age control. However, such age control has been lacking for even the penultimate glacial termination (T-II), which culminated in a sea-level highstand during the last interglacial period that was several metres above present4. Here we show that Heinrich Stadial 11 (HS11), a prominent North Atlantic cold episode5, 6, occurred between 135 {$\pm$} 1 and 130 {$\pm$} 2 thousand years ago and was linked with rapid sea-level rise during T-II. Our conclusions are based on new and existing6, 7, 8, 9 data for T-II and the last interglacial that we collate onto a single, radiometrically constrained chronology. The HS11 cold episode5, 6 punctuated T-II and coincided directly with a major deglacial meltwater pulse, which predominantly entered the North Atlantic Ocean and accounted for about 70 per cent of the glacial?interglacial sea-level rise8, 9. We conclude that, possibly in response to stronger insolation and CO2 forcing earlier in T-II, the relationship between climate and ice-volume changes differed fundamentally from that of T-I. In T-I, the major sea-level rise clearly post-dates3, 10, 11 Heinrich Stadial 1. We also find that HS11 coincided with sustained Antarctic warming, probably through a bipolar seesaw temperature response12, and propose that this heat gain at high southern latitudes promoted Antarctic ice-sheet melting that fuelled the last interglacial sea-level peak.