Abstract
The Indian Ocean Dipole (IOD) is the dominant mode of interannual variability over the tropical Indian Ocean (IO) and its future changes are projected to impact the climate and weather of Australia, East Africa, and Indonesia. Understanding the response of the IOD to a warmer climate has been largely limited to studies of individual coupled general circulation models or multi-model ensembles. This has provided valuable insight into the IOD’s projected response to increasing greenhouse gases but has limitations in accounting for the role of internal climate variability. Using the Community Earth System Model Large Ensemble (CESM-LE), the IOD is examined in thirty-five present-day and future simulations to determine how internal variability influences properties of the IOD and their response to a warmer climate. Despite small perturbations in the initial conditions as the only difference between ensemble members, significant relationships between the mean state of the IO and the IOD arise, leading to a spread in the projected IOD responses to increasing greenhouse gases. This is driven by the positive Bjerknes feedback, where small differences in mean thermocline depth, which are caused by internal climate variability, generate significant variations in IOD amplitude, skewness, and the climatological zonal sea surface temperature gradient.
Highlights
Interannual variability in the Indian Ocean (IO) is dominated by the Indian Ocean Dipole (IOD) which develops in austral winter (June, July, August; JJA) and peaks in spring (September, October, November; SON)[1,2]
Models partaking in the Coupled Model Intercomparison Project phase 5 (CMIP5) tend to exhibit a positive IOD-like warming pattern over the tropical IO, with weaker warming in the eastern equatorial IO (EEIO) (WEIO) and an easterly wind trend[17,18]
The influence of the mean thermocline state on IOD properties is clearly evident in the strong correlations exhibited in Community Earth System Model Large Ensemble (CESM-LE) but it is important to remember that there may be biases in the model
Summary
Interannual variability in the Indian Ocean (IO) is dominated by the Indian Ocean Dipole (IOD) which develops in austral winter (June, July, August; JJA) and peaks in spring (September, October, November; SON)[1,2]. Models partaking in the Coupled Model Intercomparison Project phase 5 (CMIP5) tend to exhibit a positive IOD-like warming pattern over the tropical IO, with weaker (stronger) warming in the EEIO (WEIO) and an easterly wind trend[17,18]. This response is driven by the projected weakening of the Walker circulation in a warmer climate, which is behaviour displayed by the majority of models[23,24,25,26]. We show instead that small differences in the mean thermocline depth, which arise due to internal climate variability, can influence projected changes in IOD properties
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