Back to an ice-free future: Early Cretaceous seasonal cycles of sea surface temperature and glacier ice
Songlin He, Tianyang Wang, Robert A. Spicer, Alex Farnsworth, Andreas Mulch, Mike Widdowson, Qinghai Zhang, Fulong Cai, Paul J. Valdes, Chao Wang, Hasina Nirina Randrianaly, Jing Xie, Lin Ding
Abstract
Global ice losses will likely continue with ongoing climate warming, culminating in an almost ice-free planet analogous to that which persisted throughout much of the Cretaceous. Despite extensive research, Early Cretaceous cryosphere responses to temperature and atmospheric P CO 2 fluctuations over short, human, timescales remain uncertain. Here, we show rapid late Valanginian (~133 million years ago) seasonal fluctuations in sea surface temperature (SST) and δ 18 O mainly driven by atmospheric P CO 2 . Two distinctive features emerge: large seasonal variability of up to 15.9° ± 4.9°C in Southern Hemisphere mid-latitudes, comparable to that found today, a positive sea surface δ 18 O value related to evaporation (expressed as salinity increases), and the existence of polar ice. Model-predicted patterns of SST change match with high statistical confidence those derived from clumped isotopes in well-preserved oyster fossils from Madagascar and display consistent warm/cold seasonality. Given its relative coolness in a Cretaceous context, the late Valanginian is a valuable analog for Earth’s future climate.