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This research investigates how tropical cyclones uplift marine dimethyl sulfide (DMS), affecting SO2 levels in the upper troposphere.

April 12, 2026Open Access

DMS Uplift by Tropical Cyclones as a Source of SO 2 in the Upper Troposphere

Key Points

This research investigates how tropical cyclones uplift marine dimethyl sulfide (DMS), affecting SO2 levels in the upper troposphere.
Utilized airborne observations from ACCLIP conducted on 2 August 2022.
Applied Lagrangian particle dispersion model back trajectories to analyze DMS transport.
Performed GEOS-Chem simulations to assess DMS injection and its effects.
SO2 mixing ratios were enhanced by 4-6 times in regions impacted by tropical cyclones.
A mean DMS flux of 9.4 kg hr−1 was observed, with 8.4% of emissions penetrating above 12 km.
DMS showed a longer lifetime in the upper troposphere compared to at the surface, facilitating SO2 production.

Abstract

Abstract Airborne observations from ACCLIP on 2 August 2022, combined with Lagrangian particle dispersion model back trajectories, reveal that SO 2 mixing ratios at 14–16 km were enhanced by a factor of 4–6 in regions influenced by tropical cyclones (TCs). These enhancements are linked to rapid lofting of marine dimethyl sulfide (DMS) into the upper troposphere (UT). GEOS‐Chem simulations indicated that on 31 July 2022, TC‐scale circulation injected DMS into the UT within hours, with a mean flux of 9.4 kg hr −1 across 0.5–12 km and 8.4% of emissions penetrating above 12 km, consistent with observations of elevated DMS at the same altitudes. Because of its low solubility and longer UT lifetime (59.2 vs. 5.7 hr at the surface), DMS sustains SO 2 production that is largely resistant to wet scavenging. This TC‐driven pathway provides a significant natural SO 2 source in the UT, with implications for aerosol–cloud–climate interactions.

DMS Uplift by Tropical Cyclones as a Source of SO 2 in the Upper Troposphere

Key Points

Abstract

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