Exponential growth in big data and computing power is transforming climate science, where machine learning is playing a critical role in mapping the physics of our changing climate.
鈥淲hat is happening within the field is revolutionary,鈥 says Associate Chair and Professor , adding that because many climate-related processes 鈥 from ocean currents to melting glaciers and weather patterns 鈥 can be described with physical equations, these advancements have the potential to help us understand and predict climate in critically important ways.
Bracco is the lead author of a new review paper providing a comprehensive look at the intersection of AI and climate physics.
The result of an international collaboration between 色花堂鈥檚 Bracco, Julien Brajard (Nansen Environmental and Remote Sensing Center), Henk A. Dijkstra (Utrecht University), Pedram Hassanzadeh (University of Chicago), Christian Lessig (European Centre for Medium-Range Weather Forecasts), and Claire Monteleoni (University of Colorado Boulder), the paper, 鈥,鈥 was recently published in Nature Reviews Physics.
鈥淥ne of our team鈥檚 goals was to help people think deeply on how climate science and AI intersect,鈥 Bracco shares. 鈥淢achine learning is allowing us to study the physics of climate in a way that was previously impossible. Coupled with increasing amounts of data and observations, we can now investigate climate at scales and resolutions we鈥檝e never been able to before.鈥
Connecting hidden dots
The team showed that ML is driving change in three key areas: accounting for missing observational data, creating more robust climate models, and enhancing predictions, especially in weather forecasting. However, the research also underscores the limits of AI 鈥 and how researchers can work to fill those gaps.
鈥淢achine learning has been fantastic in allowing us to expand the time and the spatial scales for which we have measurements,鈥 says Bracco, explaining that ML could help fill in missing data points 鈥 creating a more robust record for researchers to reference. However, like patching a hole in a shirt, this works best when the rest of the material is intact.
鈥淢achine learning can extrapolate from past conditions when observations are abundant, but it can鈥檛 yet predict future trends or collect the data we need,鈥 Bracco adds. 鈥淭o keep advancing, we need scientists who can determine what data we need, collect that data, and solve problems.鈥
Modeling climate, predicting weather
Machine learning is often used when improving climate models that can simulate changing systems like our atmosphere, oceans, land, biochemistry, and ice. 鈥淭hese models are limited because of our computing power, and are run on a three-dimensional grid,鈥 Bracco explains: below the grid resolution, researchers need to approximate complex physics with simpler equations that computers can solve quickly, a process called 鈥榩arameterization鈥.
Machine learning is changing that, offering new ways to improve parameterizations, she says. 鈥淲e can run a model at extremely high resolutions for a short time, so that we don鈥檛 need to parameterize as many physical processes 鈥 using machine learning to derive the equations that best approximate what is happening at small scales,鈥 she explains. 鈥淭hen we can use those equations in a coarser model that we can run for hundreds of years.鈥
While a full climate model based solely on machine learning may remain out of reach, the team found that ML is advancing our ability to accurately predict weather systems and some climate phenomena like El Ni帽o.
Previously, weather prediction was based on knowing the starting conditions 鈥 like temperature, humidity, and barometric pressure 鈥 and running a model based on physics equations to predict what might happen next. Now, machine learning is giving researchers the opportunity to learn from the past. 鈥淲e can use information on what has happened when there were similar starting conditions in previous situations to predict the future without solving the underlying governing equations,鈥 Bracco says. 鈥淎nd all while using orders-of-magnitude less computing resources.鈥
The human connection
Bracco emphasizes that while AI and ML play a critical role in accelerating research, humans are at the core of progress. 鈥淚 think the in-person collaboration that led to this paper is, in itself, a testament to the importance of human interaction,鈥 she says, recalling that the research was the result of a workshop organized at the 鈥 one of the team鈥檚 first in-person discussions after the Covid-19 pandemic.
鈥淢achine learning is a fantastic tool 鈥 but it's not the solution to everything,鈥 she adds. 鈥淭here is also a real need for human researchers collecting high-quality data, and for interdisciplinary collaboration across fields. I see this as a big challenge, but a great opportunity for computer scientists and physicists, mathematicians, biologists, and chemists to work together.鈥
Funding: National Science Foundation, European Research Council, Office of Naval Research, US Department of Energy, European Space Agency, Choose France Chair in AI.
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