In a tragic maritime disaster, a luxury sailing yacht was sunk off the coast of Sicily on Monday by a rare meteorological event—a waterspout. Among those missing are British billionaire Mike Lynch and Jonathan Bloomer, chairman of Morgan Stanley International. The incident has raised concerns about the increasing frequency of extreme weather events, potentially linked to climate change.
Rescue operations are still underway for the missing passengers. Fortunately, 15 others aboard the yacht, named the Bayesian, were successfully rescued, although some have been injured. Authorities are actively investigating the cause of the incident, with early reports suggesting that abnormally high water temperatures in the Mediterranean may have contributed to the formation of the destructive waterspout.
Understanding waterspouts: A meteorological perspective
Waterspouts, though similar to tornadoes, are a unique phenomenon that occurs over bodies of water. According to Jana Houser, an associate professor of meteorology at Ohio State University, “Generally speaking, a waterspout is a type of tornado that forms over water. While there are differences between the formation of a waterspout and a traditional tornado, they belong to the same meteorological family.”
The science behind a waterspout
Waterspouts form as rotating columns of air beneath thunderstorms, typically over warm water bodies. While many are relatively brief and mild, some can become intense and pose significant risks to vessels in their path. Houser explained that waterspouts can develop in various locations, including the Great Lakes in the United States and the Gulf of Mexico, wherever warm water contrasts with cooler shorelines.
Meteorologist Peter Inness from the University of Reading highlighted the critical conditions needed for waterspout formation: “Heat and humidity in the lower atmosphere are the two main requirements [for waterspout formation], and over the Mediterranean in late summer and autumn, there are plenty of both.”
Inness added that changes in wind direction with height are necessary to set up the air rotation within the waterspout. This rotation, combined with an upward motion of air under a thunderstorm over water, leads to the formation of a waterspout.
Houser added: “The thunderstorm basically ingests the rotation upward through the storm’s updraft and causes it to spin faster and faster as it does so.”
While most waterspouts are weak and short-lived, winds of over 100 mph can form quickly. “Actual wind measurements from inside waterspouts are very rare indeed,” Inness noted.
Eyewitness accounts and unusual timing
Eyewitnesses described the terrifying scene as the Bayesian vanished within 60 seconds after being struck by the violent storm in the early morning hours.
Houser noted the unusual timing of the event, stating, “You would normally expect a traditional waterspout to form during late afternoon hours after you’ve had a lot of surface heating. There’s no way this is like a traditional waterspout because it happened in the middle of the night.”
She suggested that the event might have resembled a traditional tornado, where the storm itself was rotating, explaining the intensity and destructiveness of the waterspout. The incident has reignited discussions about the impact of climate change on extreme weather events. While the connection between rising ocean temperatures and more frequent waterspouts is complex, the above-average sea temperatures around Sicily likely played a role in this event. Whether climate change is solely responsible for such incidents remains a topic of ongoing scientific investigation.
As the search for the missing passengers continues, this tragic event underscores the growing risks posed by extreme weather phenomena, particularly in regions where climate change is warming the seas. The loss of the Bayesian and the lives still unaccounted for serve as a stark reminder of the power and unpredictability of nature.