Litcius/Paper detail

Integrating Automated Electrochemistry and High‐Throughput Characterization with Machine Learning to Explore Si─Ge─Sn Thin‐Film Lithium Battery Anodes

Alexey O. Sanin, Jackson K. Flowers, Tobias H. Piotrowiak, Frederic Felsen, Leon Merker, Alfred Ludwig, Dominic Bresser, Helge S. Stein

2025Advanced Energy Materials21 citationsDOIOpen Access PDF

Abstract

Abstract High‐performance batteries need accelerated discovery and optimization of new anode materials. Herein, we explore the Si─Ge─Sn ternary alloy system as a candidate fast‐charging anode materials system by utilizing a scanning droplet cell (SDC) as an autonomous electrochemical characterization tool with the goal of subsequent upscaling. As the SDC is performing experiments sequentially, an exploration of the entire ternary space is unfeasible due to time constraints. Thus, closed‐loop optimization, guided by real‐time data analysis and sequential learning algorithms, is utilized to direct experiments. The lead material identified is scaled up to a coin cell to validate the findings from the autonomous millimeter‐scale thin‐film electrochemical experimentation. Explainable machine learning (ML) models incorporating data from high‐throughput Raman spectroscopy and X‐ray diffraction (XRD) are used to elucidate the effect of short and long‐range ordering on material performance.

Topics & Concepts

Materials scienceCharacterization (materials science)ElectrochemistryAnodeThroughputLithium (medication)Battery (electricity)Lithium batteryThin filmNanotechnologyOptoelectronicsChemical engineeringElectrodeComputer sciencePhysical chemistryIonOrganic chemistryPower (physics)EngineeringTelecommunicationsPhysicsChemistryQuantum mechanicsMedicineIonic bondingWirelessEndocrinologyMachine Learning in Materials ScienceAdvancements in Battery MaterialsSemiconductor materials and interfaces