A23M-06
Holocene constraints on simulated tropical Pacific climate 

Tuesday, 15 December 2015: 14:55
3005 (Moscone West)
Julien Emile-Geay, University of Southern California, Los Angeles, CA, United States, Kim M Cobb, Georgia Institute of Technology Main Campus, Earth and Atmospheric Sciences, Atlanta, GA, United States, Matthieu Carre, Université Montpellier 2, UM2-CNRS-IRD, Institut des Sciences de l’Evolution,, Montpellier, France, Pascale Braconnot, CEA Saclay DSM / LSCE, Gif sur Yvette, France, Julie Leloup, LOCEAN-IPSL / UPMC, Paris, France, Yuxin Zhou, University of Southern California, Earth Sciences, Los Angeles, CA, United States, Sandy P Harrison, University of Reading, Reading, United Kingdom, Thierry Correge, University of Bordeaux 1, Talence, France, Helen V Mcgregor, University of Wollongong, Wollongong, Australia, Matthew Collins, University of Exeter, CEMPS, Exeter, United Kingdom, Robin Driscoll, University of Edinburgh, School of Geosciences, Edinburgh, United Kingdom, Mary Elliot, University de Nantes, Nantes, France, Birgit Schneider, University of Kiel - CAU, Institut für Geowissenschaften, Kiel, Germany and Alexander William Tudhope, University of Edinburgh, Edinburgh, United Kingdom
Abstract:
The El Niño-Southern Oscillation (ENSO) influences climate and weather worldwide, so uncertainties in its response to external forcings contribute to the spread in global climate projections. Theoretical and modeling studies have argued that such forcings may affect ENSO either via the seasonal cycle, the mean state, or extratropical influences, but these mechanisms are poorly constrained by the short instrumental record. Here we synthesize a pan-Pacific network of high-resolution marine biocarbonates spanning discrete snapshots of the Holocene (past 10, 000 years of Earth's history), which we use to constrain a set of global climate model (GCM) simulations via a forward model and a consistent treatment of uncertainty. Observations suggest important reductions in ENSO variability throughout the interval, most consistently during 3-5 kyBP, when approximately 2/3 reductions are inferred. The magnitude and timing of these ENSO variance reductions bear little resemblance to those sim- ulated by GCMs, or to equatorial insolation. The central Pacific witnessed a mid-Holocene increase in seasonality, at odds with the reductions simulated by GCMs. Finally, while GCM aggregate behavior shows a clear inverse relationship between seasonal amplitude and ENSO-band variance in sea-surface temperature, in agreement with many previous studies, such a relationship is not borne out by these observations. Our synthesis suggests that tropical Pacific climate is highly variable, but exhibited millennia-long periods of reduced ENSO variability whose origins, whether forced or unforced, contradict existing explanations. It also points to deficiencies in the ability of current GCMs to simulate forced changes in the tropical Pacific seasonal cycle and its interaction with ENSO, highlighting a key area of growth for future modeling efforts.