Abstract
The Tropical Pacific Ocean displays persistently cool sea surface temperature (SST) anomalies that last several years to a decade, with either no El Niño events or a few weak El Niño events. These cause large-scale droughts in the extratropics, including major North American droughts such as the 1930s Dust Bowl, and also modulate the global mean surface temperature. Here we show that two models with different levels of complexity—the Zebiak–Cane intermediate model and the Geophysical Fluid Dynamics Laboratory Coupled Model version 2.1—are able to produce such periods in a realistic manner. We then test the predictability of these periods in the Zebiak–Cane model using an ensemble of experiments with perturbed initial states. Our results show that in most cases the cool mean state is predictable. We then apply this method to make retrospective forecasts of shifts in the decadal mean state and to forecast the mean state of the Tropical Pacific Ocean for the upcoming decade. Our results suggest that the Pacific will undergo a shift to a warmer mean state after the 2015–2016 El Niño. This could imply the cessation of the drier than normal conditions that have generally afflicted southwest North America since the 1997–1998 El Niño, as well as the twenty-first-century pause in global warming. Implications for our understanding of the origins of such persistent cool states and the possibility of improving predictions of large-scale droughts are discussed.
Highlights
The Tropical Pacific Ocean is a dominant force in global climate variability
This oscillation has a period of 2–7 years, and there is a well-known asymmetry between the duration of La Niña events, which tend to last 1–2 years, and El Niño events, which usually last only for 2–4 seasons (Okumura and Deser 2010)
If neither the ZC model nor this model are able to produce this variability, there may be something fundamental missing from the simulations, or it may be the case that radiative forcing in some form is required to give rise to persistent cool states.The observational datasets used were the Kaplan Extended Sea Surface Temperature Version 2 (KSST) (Kaplan et al 1998), a gridded sea surface temperature (SST) dataset that spans the period from 1856 to the present, and station precipitation data from the Global Historical Climatology Network (GHCN) (Vose et al 1992) developed and maintained by the National Oceanic and Atmospheric Administration’s National Climate Data Center (NOAA NCDC) and the U.S Department of Energy’s Carbon Dioxide Informational Analysis Center (DoE CDIAC)
Summary
The Tropical Pacific Ocean is a dominant force in global climate variability. The coupling between atmosphere and ocean dynamics in this region gives rise to a richly complex system that is able to produce a wide range of behaviors on a variety of timescales. A 4000-year unforced simulation from this model with no variability in solar or aerosol forcing (Wittenberg et al 2014) was analyzed in this study.It is useful to examine persistent cool states in this particular model as it has been used to study the Tropical Pacific system both on decadal (Wittenberg et al 2014) and interannual (Kug et al 2010; Takahashi et al 2011) timescales.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
