TY - JOUR
T1 - Autonomous Battery Optimization by Deploying Distributed Experiments and Simulations
AU - Vogler, Monika
AU - Steensen, Simon Krarup
AU - Ramírez, Francisco Fernando
AU - Merker, Leon
AU - Busk, Jonas
AU - Carlsson, Johan Martin
AU - Rieger, Laura Hannemose
AU - Zhang, Bojing
AU - Liot, François
AU - Pizzi, Giovanni
AU - Hanke, Felix
AU - Flores, Eibar
AU - Hajiyani, Hamidreza
AU - Fuchs, Stefan
AU - Sanin, Alexey
AU - Gaberšček, Miran
AU - Castelli, Ivano Eligio
AU - Clark, Simon
AU - Vegge, Tejs
AU - Bhowmik, Arghya
AU - Stein, Helge Sören
N1 - Publisher Copyright:
© 2024 The Author(s). Advanced Energy Materials published by Wiley-VCH GmbH.
PY - 2024
Y1 - 2024
N2 - Non-trivial relationships link individual materials properties to device-level performance. Device optimization therefore calls for new automation approaches beyond the laboratory bench with tight integration of different research methods. This study demonstrates a Materials Acceleration Platform (MAP) in the field of battery research based on the problem-agnostic Fast INtention-Agnostic LEarning Server (FINALES) framework, which integrates simulations and physical experiments while leaving the active control of the hardware and software resources executing experiments or simulations with the partners running the respective units. This decentralization of control is a distinctive feature of MAPs using the FINALES framework. The connected capabilities entail the formulation and characterization of electrolytes, cell assembly and testing, early lifetime prediction, and ontology-mapped data storage provided by institutions distributed across Europe. The infrastructure is used to optimize the ionic conductivity of electrolytes and the End Of Life (EOL) of lithium-ion coin cells by varying the electrolyte formulation. Trends in ionic conductivity are rediscovered and the effect of the electrolyte formulation on the EOL is investigated. Further, the capability of this MAP to bridge diverse research modalities, scales, and institutions enabling system-level investigations under asynchronous conditions while handling concurrent workflows on the material- and system-level is shown, demonstrating true intention-agnosticism.
AB - Non-trivial relationships link individual materials properties to device-level performance. Device optimization therefore calls for new automation approaches beyond the laboratory bench with tight integration of different research methods. This study demonstrates a Materials Acceleration Platform (MAP) in the field of battery research based on the problem-agnostic Fast INtention-Agnostic LEarning Server (FINALES) framework, which integrates simulations and physical experiments while leaving the active control of the hardware and software resources executing experiments or simulations with the partners running the respective units. This decentralization of control is a distinctive feature of MAPs using the FINALES framework. The connected capabilities entail the formulation and characterization of electrolytes, cell assembly and testing, early lifetime prediction, and ontology-mapped data storage provided by institutions distributed across Europe. The infrastructure is used to optimize the ionic conductivity of electrolytes and the End Of Life (EOL) of lithium-ion coin cells by varying the electrolyte formulation. Trends in ionic conductivity are rediscovered and the effect of the electrolyte formulation on the EOL is investigated. Further, the capability of this MAP to bridge diverse research modalities, scales, and institutions enabling system-level investigations under asynchronous conditions while handling concurrent workflows on the material- and system-level is shown, demonstrating true intention-agnosticism.
KW - battery research
KW - Bayesian optimization
KW - decentralized
KW - electrolyte
KW - materials acceleration platform
KW - self-driving laboratory
UR - http://www.scopus.com/inward/record.url?scp=85206578971&partnerID=8YFLogxK
U2 - 10.1002/aenm.202403263
DO - 10.1002/aenm.202403263
M3 - Article
AN - SCOPUS:85206578971
SN - 1614-6832
JO - Advanced Energy Materials
JF - Advanced Energy Materials
ER -