What question did this study set out to answer?

The research aims to understand the role of Middle East dust as a driver of Indian Ocean Dipole (IOD) variability.

February 2, 2026Open Access

Middle East dust as an important external driver of the Indian Ocean Dipole

Key Points

The research aims to understand the role of Middle East dust as a driver of Indian Ocean Dipole (IOD) variability.
Satellite observations were utilized to analyze dust emissions.
Reanalysis data was examined to assess IOD variability from 1980 to 2020.
Climate model experiments were conducted to investigate the effects of dust on ocean temperatures and wind patterns.
Middle East dust accounts for approximately 36% of interannual IOD variance.
Dust emissions have a stronger effect on IOD variability than El Niño-Southern Oscillation during boreal autumn.
Reduced dust levels lead to warming in the western Indian Ocean and changes in wind patterns, amplifying IOD effects.

Abstract

The Indian Ocean Dipole (IOD) strongly influences Indo-Pacific climate extremes, yet its drivers remain incompletely understood. Using satellite observations, reanalysis, and climate model experiments, we identify Middle East dust emissions as a major external driver of IOD variability. Observational evidence shows that dust over the 1980-2020 period account for ~36% of interannual IOD variance, surpassing El Niño-Southern Oscillation as the main driver during boreal autumn. Climate simulations confirm that reduced dust enhances warming in the western Indian Ocean and inducing easterly winds that shoal the eastern thermocline. These anomalies trigger Bjerknes and wind-evaporation-sea surface temperature feedbacks, amplifying a positive IOD pattern, and vice versa. Our findings reveal a powerful dust-IOD teleconnection, highlighting the need to incorporate aerosol forcing into seasonal forecasts and climate projections.

Middle East dust as an important external driver of the Indian Ocean Dipole

Key Points

Abstract

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