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This illustration by Benjamin Storer demonstrates oceanic weather patterns and their relationship with global climate.
Scientists have found the first direct evidence linking weather systems in the ocean with global climate. Led by Hussein Aluie, an associate professor in the University of Rochester’s Department of Mechanical Engineering and staff scientist at the University’s Laboratory for Laser Energetics, the team reported their findings in Science Advances.
Ocean weather patterns function similarly to land weather but operate on different time and length scales, explains lead author Benjamin Storer, a research associate in Aluie’s Turbulence and Complex Flow Group. While land weather patterns last a few days and span about 500 kilometers, oceanic weather patterns like swirling eddies last three to four weeks but are about one-fifth the size.
“Scientists have long speculated that oceanic motions communicate with climate scales, but it has always been vague because it wasn’t clear how to disentangle this complex system to measure their interactions,” says Aluie. “We developed a framework that can do exactly that. What we found was not what people were expecting because it requires the mediation of the atmosphere.”
The group’s goal was to understand how energy passes through different channels in the ocean throughout the planet. They used a mathematical method developed by Aluie in 2019, which was subsequently implemented into an advanced code by Storer and Aluie, that allowed them to study energy transfer across different patterns ranging from the circumference of the globe down to 10 kilometers. These techniques were then applied to ocean datasets from an advanced climate model and from satellite observations.
The study revealed that ocean weather systems are both energized and weakened when interacting with climate scales, and in a pattern that mirrors the global atmospheric circulation. The researchers also found that an atmospheric band near the equator called the “intertropical convergence zone,” which produces 30% of global precipitation, causes an intense amount of energy transfer, and produces ocean turbulence.
Storer and Aluie say that studying such complex fluid motion happening at multiple scales is not easy, but that it has advantages over previous attempts to link weather to climate change. They believe the team’s work creates a promising framework for better understanding the climate system.
“There’s a lot of interest in how global warming and our changing climate is influencing extreme weather events,” says Aluie. “Usually, such research efforts are based on statistical analysis that requires expansive data to have confidence in the uncertainties.