Abstract
There is increasing evidence that millennial-scale climate variability played an active role on orbital-scale climate changes, but the mechanism for this remains unclear. A 230Th-dated stalagmite δ18O record between 88 and 22 thousand years (ka) ago from Yongxing Cave in central China characterizes changes in Asian monsoon (AM) strength. After removing the 65°N insolation signal from our record, the δ18O residue is strongly anti-phased with Antarctic temperature variability on sub-orbital timescales during the Marine Isotope Stage (MIS) 3. Furthermore, once the ice volume signal from Antarctic ice core records were removed and extrapolated back to the last two glacial-interglacial cycles, we observe a linear relationship for both short- and long-duration events between Asian and Antarctic climate changes. This provides the robust evidence of a link between northern and southern hemisphere climates that operates through changes in atmospheric circulation. We find that the weakest monsoon closely associated with the warmest Antarctic event always occurred during the Terminations. This finding, along with similar shifts in the opal flux record, suggests that millennial-scale events play a key role in driving the deglaciation through positive feedbacks associated with enhanced upwelling and increasing CO2.
Highlights
Mean annual temperature are ~1,000 mm and ~12 °C at the cave site, respectively
The temperature inside the cave is about 14 °C. Rainfall in this zone is controlled by the seasonal changes in solar radiation which result in a migration of the intertropical convergence zone (ITCZ) and changes in monsoon intensity
Our new record allows for a better constraint on the AM events that occur on time scales from millennia to sub-millennia and shorter, such as the double peak characterizing Dansgaard-Oeschger event (DO) 15
Summary
The Sanbao records typically exhibit lower average absolute δ18O values than the Hulu records by ~1.6%, and the Yongxing records by ~0.7% These offsets mainly result from continental effects, elevation effects[5,14], and/or from differences in the time of stored water at these sites. The Antarctic EDC temperature record includes an ice-volume signal typical of “the 100 ka cycle” For this reason, we decompose the millennial-scale variability from the EDC temperature records by removal of the LR04 marine stack, an indicator of ice-volume signal. 2) record on the AICC2012 chronology[22] and the LR04 marine stack[21], we generated a set of detrended EDC data (ΔδD) by subtracting the ice-volume signal from the Antarctic EDC δD record.
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