ENSO-driven energy budget perturbations in observations and CMIP models

Michael Mayer,Kevin E Trenberth,Leopold Haimberger,John T Fasullo

doi:10.1007/s00382-016-3057-z

Michael Mayer, Kevin E Trenberth + Show 2 more

Open Access

https://doi.org/10.1007/s00382-016-3057-z

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Abstract

Various observation-based datasets are employed to robustly quantify changes in ocean heat content (OHC), anomalous ocean–atmosphere energy exchanges and atmospheric energy transports during El Nino-Southern Oscillation (ENSO). These results are used as a benchmark to evaluate the energy pathways during ENSO as simulated by coupled climate model runs from the CMIP3 and CMIP5 archives. The models are able to qualitatively reproduce observed patterns of ENSO-related energy budget variability to some degree, but key aspects are seriously biased. Area-averaged tropical Pacific OHC variability associated with ENSO is greatly underestimated by all models because of strongly biased responses of net radiation at top-of-the-atmosphere to ENSO. The latter are related to biases of mean convective activity in the models and project on surface energy fluxes in the eastern Pacific Intertropical Convergence Zone region. Moreover, models underestimate horizontal and vertical OHC redistribution in association with the generally too weak Bjerknes feedback, leading to a modeled ENSO affecting a too shallow layer of the Pacific. Vertical links between SST and OHC variability are too weak even in models driven with observed winds, indicating shortcomings of the ocean models. Furthermore, modeled teleconnections as measured by tropical Atlantic OHC variability are too weak and the tropical zonal mean ENSO signal is strongly underestimated or even completely missing in most of the considered models. Results suggest that attempts to infer insight about climate sensitivity from ENSO-related variability are likely to be hampered by biases in ENSO in CMIP simulations that do not bear a clear link to future changes.

Highlights

El Niño-Southern Oscillation (ENSO) is the preeminent mode of global internal climate variability
We investigate the strength of the relationship between sea surface temperature (SST) and ocean heat content (OHC) for various layers by comparing the temporal standard deviation of the N3.4 series from the respective datasets to the temporal standard deviation of OHC of the upper 100 m (Fig. 2a) and the upper 700 m (Fig. 2c) of the ocean averaged over the same area as the N3.4 SST index
The zonal mean atmospheric energy export response to ENSO (Fig. 11b) is relatively small owing to compensating responses of the tropical Pacific and the other tropical basins

Summary

Introduction

El Niño-Southern Oscillation (ENSO) is the preeminent mode of global internal climate variability It leads to strong anomalies of the atmosphere–ocean energy budget in the tropical Pacific Ocean, and on a global scale. One prevailing theory of ENSO is the recharge-discharge hypothesis by Wyrtki (1975) updated by Suarez and Schopf (1988) and Jin (1997) It is centered on a build up of ocean heat in the tropical western Pacific in the cool phase, and in the course of the El Niño event, the heat is moved across the Pacific and polewards within the ocean. This process involves lateral and vertical redistribution of heat within the basin (Roemmich and Gilson 2011), increasing the area of warm surface water leading to heat loss to the atmosphere primarily by enhanced evaporation

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