Millennial-scale variability to 735 ka: High-resolution climate records from Santa Barbara Basin, CA

Determining the ultimate cause and effect of millennial-scale climate variability remains an outstanding problem in paleoceanography, partly due to the lack of high-resolution records predating the last glaciation. Recent cores from Santa Barbara Basin provide similar to 2500-5700 year windows of climate with similar to 10-50 year resolution. Ages for three cores, determined by seismic stratigraphic correlation, oxygen isotope stratigraphy, and biostratigraphy, date to similar to 293 ka (MIS 8), similar to 450 ka (MIS 12), and similar to 735 ka (MIS 18). These records sample the Late Pleistocene, during which the 100 kyr cycle strengthened and the magnitude of glacial-interglacial cyclicity increased. Thus, these records provide a test of the dependence of millennial-scale behavior on variations in glacial-interglacial cyclicity. The stable isotopic (delta O-18) composition of planktonic foraminifera shows millennial-scale variability in all three intervals, with similar characteristics (duration, cyclicity) to those previously documented during MIS 3 at this site. Stadial G. bulloides delta O-18 values are 2.75-1.75 parts per thousand (average 2.25 parts per thousand) and interstadial values are 1.75-0.5 parts per thousand (average 1 parts per thousand), with rapid (decadal-scale) interstadial and stadial initiations of 1-2 parts per thousand, as in MIS 3. Interstadials lasted similar to 250-1600 years and occurred every similar to 650-1900 years. Stadial paleotemperatures were 3.5-9.5 degrees C and interstadial paleotemperatures were 7.5-13 degrees C. Upwelling, evidenced by planktonic foraminiferal assemblages and delta C-13, increased during interstadials, similar to MIS 3; high productivity during some stadials was reminiscent of the Last Glacial Maximum. This study builds upon previous records in showing that millennial-scale shifts were an inherent feature of Northern Hemisphere glacial climates since 735 ka, and they remained remarkably constant in the details of their amplitude, cyclicity, and temperature variability.