金属锂
电解质
主动学习(机器学习)
锂(药物)
计算机科学
溶剂
材料科学
金属
贝叶斯优化
化学空间
频数推理
工作(物理)
贝叶斯推理
纳米技术
高氯酸锂
电池(电)
钥匙(锁)
化学工程
工艺工程
储能
机器学习
人工智能
贝叶斯概率
作者
Peiyuan Ma,Ritesh Kumar,Ke-Hsin Wang,Chibueze V. Amanchukwu
标识
DOI:10.1038/s41467-025-63303-7
摘要
Anode-free or ‘zero-excess’ lithium metal batteries offer high energy density compared to current lithium-ion batteries but require electrolyte innovation to extend cycle life. Due to the lack of universal design principles, electrolyte development for anode-free lithium metal batteries is slow and incremental and mainly driven by trial-and-error. Here, we demonstrate the use of active learning as an alternative approach to accelerate electrolyte discovery for anode-free lithium metal batteries. Unlike conventional data-intensive frequentist machine learning techniques, our active learning framework employs sequential Bayesian experimental design with Bayesian model averaging to efficiently identify optimal candidates in typical data-scarce and noisy label settings. Using capacity retention in real Cu||LiFePO4 cells as the target property, our approach integrates experimental feedback to iteratively refine predictions. Starting with just 58 data points from an in-house cycling dataset, the active learning framework explored a virtual search space of 1 million electrolytes, rapidly converging on optimal candidates. After seven active learning campaigns with about ten electrolytes tested in each, four distinct electrolyte solvents are identified that rival state-of-the-art electrolytes in performance. This work showcases the promise of active learning approaches in navigating large electrolyte chemical spaces for next-generation batteries. Next-generation batteries require innovative electrolytes, but conventional methods are tedious and costly. Here, authors develop an active learning framework to rapidly identify seven efficient electrolytes for anode-free lithium-metal batteries, accelerating electrolyte discovery.
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