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Machine Learning Modeling for Accelerated Battery Materials Design in the Small Data Regime

Austin D. Sendek, Brandi Ransom, Ekin D. Cubuk, Lenson A. Pellouchoud, Jagjit Nanda, Evan J. Reed

2022Advanced Energy Materials102 citationsDOIOpen Access PDF

Abstract

Abstract Machine learning (ML)‐based approaches to battery design are relatively new but demonstrate significant promise for accelerating the timeline for new materials discovery, process optimization, and cell lifetime prediction. Battery modeling represents an interesting and unconventional application area for ML, as datasets are often small but some degree of physical understanding of the underlying processes may exist. This review article provides discussion and analysis of several important and increasingly common questions: how ML‐based battery modeling works, how much data are required, how to judge model performance, and recommendations for building models in the small data regime. This article begins with an introduction to ML in general, highlighting several important concepts for small data applications. Previous ionic conductivity modeling efforts are discussed in depth as a case study to illustrate these modeling concepts. Finally, an overview of modeling efforts in major areas of battery design is provided and several areas for promising future efforts are identified, within the context of typical small data constraints.

Topics & Concepts

TimelineBattery (electricity)Context (archaeology)Computer scienceProcess (computing)Small dataData scienceExperimental dataMachine learningIndustrial engineeringArtificial intelligenceSystems engineeringEngineeringPower (physics)BiologyQuantum mechanicsPaleontologyMathematicsArchaeologyHistoryPhysicsStatisticsOperating systemMachine Learning in Materials ScienceAdvanced Battery Technologies ResearchAdvancements in Battery Materials
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