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North Atlantic Faces More Hurricane Clusters as Climate Warms

Magazine Article
07 October 2025

The formation of cluster cyclones, not just luck...

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Satellite image of the Atlantic Ocean showing five named storms: Sally, Paulette, Rene, Teddy, and Vicky, with each storm labeled over its location.
Tropical cyclone cluster events over the North Atlantic - This NOAA's GOES-16 satellite image taken on 14 September 2020 shows five tropical systems spinning in the Atlantic basin at the same time. From left to right: Hurricane Sally in the Gulf of Mexico, Hurricane Paulette east of the Carolinas, the remnants of Tropical Storm Rene in the central Atlantic, and Tropical Storms Teddy and Vicky in the eastern Atlantic. A total of 10 named storms formed in September 2020 — the most for any month on record.
(Image NOAA)

Tropical cyclones, commonly known as typhoons or hurricanes, can form in clusters and impact coastal regions back-to-back. For example, Hurricanes Harvey, Irma and Maria hit the U.S. sequentially within one month in 2017. When Hurricane Maria struck, the Federal Emergency Management Agency failed to provide adequate support to victims in Puerto Rico because most rescue resources and specialized disaster staffers were deployed for the responses to Hurricanes Harvey and Irma. A new study published in Nature Climate Change confirms that these hurricane clusters have become more frequent in the North Atlantic in recent decades – a trend projected to continue.

Tropical cyclone clusters describe events when two or more tropical cyclones present simultaneously within the same basin. This phenomenon is not rare, historically only 40% of tropical cyclones appeared alone. Beyond the combined impacts of individual storms, tropical cyclone clusters can cause disproportionate damage as coastal communities and infrastructures need time to bounce back from the impact of the first storm. Understanding tropical cyclone clusters and their future is thus important for coastal risk management.

Analysing the historical observation of tropical cyclones, the study’s authors found that during the past few decades, the likelihood of a tropical cyclone cluster decreased in the Northwestern Pacific basin, while it increased in North Atlantic basin. “We tried to develop a probabilistic framework to understand this trend,” said Dazhi Xi, a climatologist at Hong Kong University, China, who co-led the study and developed the methodology. “If tropical cyclone clusters are formed by chance, then only storm frequency, storm duration, and storm seasonality can impact the chance. So, as a first attempt we simulated the formation of tropical cyclone clusters by probabilistic modelling, considering only these three mechanisms, and hoped we could find why tropical cyclone clusters changed in the past decades.”

However, the probabilistic model was only partly successful. For some years, it significantly underestimates the chance of a tropical cyclone cluster. That is because it is not simply by chance that some storms coexist with other storms, it is rather that they have physical linkage. “What previously seemed like a failed statistical model became a powerful tool that can distinguish physically linked tropical cyclone clusters from those that occur by pure chance,” said Wen Zhou, a climatologist at Fudan University and the corresponding author of the study. In the years that the probabilistic model fails, the authors found that synoptic scale waves, a series of train-like atmospheric disturbances, enhanced the likelihood of tropical cyclone cluster formation.
The study further discovered that the La-Niña-like global warming pattern, characterized by slower warming in the Eastern Pacific compared to the Western Pacific, is the reason behind the observed shifts in tropical cyclone cluster hotspot. “The warming pattern not only modulates the frequency of tropical cyclones in the North Atlantic and Northwestern Pacific basins but also impacts the strength of the synoptic scale waves, together causing the shift of tropical cyclone cluster hotspot from Northwestern Pacific to North Atlantic basin,” said Zheng-Hang Fu, a PhD student at Fudan University who co-led the study.
The research establishes a probabilistic baseline model for investigating tropical cyclone cluster events and their underlying physical mechanisms. This framework not only explains the observed shift of tropical cyclone cluster hotspot from the Northwestern Pacific to the North Atlantic basin, but also provides a transferable methodology applicable to other ocean basins worldwide. Importantly, the authors identify the North Atlantic as an emerging hotspot for tropical cyclone clusters in recent decades. This finding calls for heightened attention from Atlantic coastal nations, urging them to develop proactive strategies against these compounding hazards.

Reference

Fu, Z.H., D. Xi, S.-P. Xie, W. Zhou, N. Lin, J. Zhao, X. Wang, and J.C.L. Chan, 2025: Shifting hotspot of tropical cyclone clusters in a warming climate. Nature Climate Change, 15. https://doi.org/10.1038/s41558-025-02397-9