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Ocean currents show global intensification of weak tropical cyclones

Guihua Wang (), Lingwei Wu, Wei Mei and Shang-Ping Xie
Additional contact information
Guihua Wang: Fudan University
Lingwei Wu: Fudan University
Wei Mei: University of North Carolina at Chapel Hill
Shang-Ping Xie: University of California San Diego

Nature, 2022, vol. 611, issue 7936, 496-500

Abstract: Abstract Theory1 and numerical modelling2 suggest that tropical cyclones (TCs) will strengthen with rising ocean temperatures. Even though models have reached broad agreement on projected TC intensification3–5, observed trends in TC intensity remain inconclusive and under active debate6–10 in all ocean basins except the North Atlantic, where aircraft reconnaissance data greatly reduce uncertainties11. The conventional satellite-based estimates are not accurate enough to ascertain the trend in TC intensity6,11, suffering from contamination by heavy rain, clouds, breaking waves and spray12. Here we show that weak TCs (that is, tropical storms to category-1 TCs based on the Saffir–Simpson scale) have intensified in all ocean basins during the period 1991–2020, based on huge amounts of highly accurate ocean current data derived from surface drifters. These drifters have submerged ‘holy sock’ drogues at 15 m depth to reduce biases induced by processes at the air–sea interface and thereby accurately measure near-surface currents, even under the most destructive TCs. The ocean current speeds show a robust upward trend of ~4.0 cm s−1 per decade globally, corresponding to a positive trend of 1.8 m s−1 per decade in the TC intensity. Our analysis further indicates that globally TCs have strengthened across the entirety of the intensity distribution. These results serve as a historical baseline that is crucial for assessing model physics, simulations and projections given the failure of state-of-the-art climate models in fully replicating these trends13.

Date: 2022
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DOI: 10.1038/s41586-022-05326-4

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