Illustrations of discovery learning process
An agentic AI tool for battery researchers harnesses data from previous battery designs to predict the cycle life of new battery concepts. With information from just 50 cycles, the tool—developed at University of Michigan Engineering—can predict how many charge-discharge cycles the battery can undergo before its capacity drops below 90 percent of its design capacity.
This could save months to years of testing, depending on the conditions of cycling experiments, as well as substantial electrical power during battery prototyping and testing. The team estimates that the cycle lives of new battery designs could be predicted with just 5% of the energy and 2% of the time required by conventional testing.
"When we learn from the historical battery designs, we leverage physics-based features to construct a generalizable mapping between early-stage tests and cycle life," said Ziyou Song , U-M assistant professor of electrical and computer engineering and corresponding author of the study in Nature . "We can minimize experimental efforts and achieve accurate prediction performance for new battery designs."
The study was funded by the battery company Farasis Energy USA in California, which also provided battery cells and data from its design and testing to assess how well the model—trained only on free, public data—performed.
The tool is inspired by a teaching approach known as discovery learning, or learning by doing. A student learning in this way has a problem to solve and resources to help discover the solution, while drawing on their own experiences and prior knowledge. Over the course of solving many problems, the student no longer needs the resources to solve similar ones—they have internalized the knowledge and skills.
"Discovery learning is a general machine-learning approach that may be extended to other scientific and engineering domains," said Jiawei Zhang , U-M doctoral candidate in electrical and computer engineering and the first author of this study, who had the initial inspiration to design a team of AI agents that could simulate this mode of learning.
The team designated an AI "learner" that would predict the cycle life for a given battery design and cycling conditions, such as temperature and current. The learner chooses a few battery candidates that would fill gaps in its knowledge, to be built and run for about 50 cycles. The results of those experiments flow to an "interpreter," which accesses historical data and runs calculations with a physics-based battery simulator. The "oracle" then makes cycle life predictions for the experimental batteries based on the historical data and calculations provided.
Finally, the learner combines the new information with previous predictions to estimate the cycle life of the new battery design. Even with experiments, the discovery learning system provides huge time and energy savings, with the potential to improve further as the learner accumulates enough knowledge to make predictions without running the discovery loop.
Next-gen lithium-ion batteries are very different from previous iterations—in chemistry, structure and materials—but the team argues that there are parallels among them that may help predict how new designs will perform. Rather than using simple statistical features from current and voltage signals, the interpreter leverages underlying physical properties to establish commonalities among different batteries.
With this information in hand, the oracle considers the battery in two ways: its internal characteristics—information from the interpreter about the physics and chemistry of the cell—and its operating conditions. For instance, at higher temperatures, a particular chemical change may dominate how the battery is likely to degrade, but that mechanism is less important at lower temperatures.
The team tested out their model with data and pouch cells from Farasis Energy USA. After training on a data set that included only cylindrical cells, similar to the familiar AA battery, the model could predict the performance of these larger cells. While full tests run to 1,000 cycles and can take a few months to years, 50-cycle tests take only a few days to weeks, according to the team's estimates. Testing required fewer cells, as well as fewer cycles, resulting in energy savings of about 95%.
Within battery technology, the team intends to expand the approach to other areas of performance, such as safety and charging speed. However, as discovery learning is a new scientific machine-learning approach, the team believes that others could build similar predictive tools or develop new approaches to optimization. They hope it could speed development in many disciplines bottlenecked by the need for expensive experiments, most immediately in chemistry and material design.
Researchers from the National University of Singapore also contributed to the study.
Study: Discovery learning predicts battery cycle life from minimal experiments (DOI: 10.1038/s41586-025-09951-7)
Nature