Accelerating aqueous electrolyte design with automated full-cell battery experimentation and Bayesian optimization
Jackie T. Yik, Carl Hvarfner, Jens Sjölund, Erik J. Berg, Leiting Zhang
Abstract
The integration of automation and data-driven methodologies offers a promising approach to accelerating materials discovery in energy storage research. Thus far, in battery research, coin-cell assembly has advanced to become nearly fully automated but remains largely disconnected from data-driven methods. To bridge the disconnect, this work presents a self-driving laboratory framework to accelerate electrolyte discovery by integrating automated coin-cell assembly, galvanostatic cycling of LiFePO 4 ||Li 4 Ti 5 O 12 organic-aqueous full cells, and Bayesian optimization for selecting subsequent experiments based on prior results. The study explored an organic-aqueous hybrid electrolyte system comprising four co-solvents and two lithium-conducting salts. Using this framework, cells with an optimized electrolyte cycled with at least 94% Coulombic efficiency. Additionally, online electrochemical mass spectrometry revealed that the optimized organic co-solvents successfully mitigated the parasitic hydrogen evolution reaction. The results highlight the potential of combining Bayesian optimization with autonomous full-cell experimentation while contributing new electrolyte design insights for next-generation aqueous batteries. • Stationary robotic platform, ODACell 2, combines battery testing and machine learning • Optimized electrolytes are dimethyl sulfoxide and trimethyl phosphate based • Data-driven insight suggests optimized electrolytes deviate from monosolvent systems • Operando gas analysis of optimized electrolytes shows suppressed hydrogen evolution A stationary robotic platform, ODACell 2, presents a self-driving lab framework combining Bayesian optimization with automated battery assembly, cycling, and liquid handling. It demonstrates the discovery of high-performance organic-aqueous hybrid electrolytes, achieving >94% Coulombic efficiency in full-cell cycling. Operando gas analysis shows mitigated hydrogen evolution in optimized electrolytes.