Extreme, abrupt Northern Hemisphere climate oscillations during the last glacial cycle (140,000 years ago to present) were modulated by changes in ocean circulation and atmospheric forcing. However, the variability of the Atlantic meridional overturning circulation (AMOC), which has a role in controlling heat transport from low to high latitudes and in ocean CO2 storage, is still poorly constrained beyond the Last Glacial Maximum. Here we show that a deep and vigorous overturning circulation mode has persisted for most of the last glacial cycle, dominating ocean circulation in the Atlantic, whereas a shallower glacial mode with southern-sourced waters filling the deep western North Atlantic prevailed during glacial maxima. Our results are based on a reconstruction of both the strength and the direction of the AMOC during the last glacial cycle from a highly resolved marine sedimentary record in the deep western North Atlantic. Parallel measurements of two independent chemical water tracers (the isotope ratios of (231)Pa/(230)Th and (143)Nd/(144)Nd), which are not directly affected by changes in the global cycle, reveal consistent responses of the AMOC during the last two glacial terminations. Any significant deviations from this configuration, resulting in slowdowns of the AMOC, were restricted to centennial-scale excursions during catastrophic iceberg discharges of the Heinrich stadials. Severe and multicentennial weakening of North Atlantic Deep Water formation occurred only during Heinrich stadials close to glacial maxima with increased ice coverage, probably as a result of increased fresh-water input. In contrast, the AMOC was relatively insensitive to submillennial meltwater pulses during warmer climate states, and an active AMOC prevailed during Dansgaard-Oeschger interstadials (Greenland warm periods).
Abstract. Thanks to its optimal location on the northern Brazilian margin,
core MD09-3257 records both ocean circulation and atmospheric changes. The
latter occur locally in the form of increased rainfall on the adjacent
continent during the cold intervals recorded in Greenland ice and northern
North Atlantic sediment cores (i.e., Greenland stadials). These rainfall
events are recorded in MD09-3257 as peaks in ln(Ti ∕ Ca). New sedimentary
Pa ∕ Th data indicate that mid-depth western equatorial water mass
transport decreased during all of the Greenland stadials of the last 40 kyr.
Using cross-wavelet transforms and spectrogram analysis, we assess the
relative phase between the MD09-3257 sedimentary Pa ∕ Th and
ln(Ti ∕ Ca) signals. We show that decreased water mass transport between
a depth of ∼1300 and 2300 m in the western equatorial Atlantic preceded
increased rainfall over the adjacent continent by 120 to 400 yr at
Dansgaard–Oeschger (D–O) frequencies, and by 280 to 980 yr at Heinrich-like
frequencies. We suggest that the large lead of ocean circulation changes with respect to
changes in tropical South American precipitation at Heinrich-like
frequencies is related to the effect of a positive feedback involving
iceberg discharges in the North Atlantic. In contrast, the absence of
widespread ice rafted detrital layers in North Atlantic cores during D–O
stadials supports the hypothesis that a feedback such as this was not triggered in
the case of D–O stadials, with circulation slowdowns and subsequent changes
remaining more limited during D–O stadials than Heinrich stadials.
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