English

AutoMat: Accelerated Computational Electrochemical systems Discovery

Materials Science 2022-05-16 v4 Machine Learning

Abstract

Large-scale electrification is vital to addressing the climate crisis, but several scientific and technological challenges remain to fully electrify both the chemical industry and transportation. In both of these areas, new electrochemical materials will be critical, but their development currently relies heavily on human-time-intensive experimental trial and error and computationally expensive first-principles, meso-scale and continuum simulations. We present an automated workflow, AutoMat, that accelerates these computational steps by introducing both automated input generation and management of simulations across scales from first principles to continuum device modeling. Furthermore, we show how to seamlessly integrate multi-fidelity predictions such as machine learning surrogates or automated robotic experiments "in-the-loop". The automated framework is implemented with design space search techniques to dramatically accelerate the overall materials discovery pipeline by implicitly learning design features that optimize device performance across several metrics. We discuss the benefits of AutoMat using examples in electrocatalysis and energy storage and highlight lessons learned.

Keywords

Cite

@article{arxiv.2011.04426,
  title  = {AutoMat: Accelerated Computational Electrochemical systems Discovery},
  author = {Emil Annevelink and Rachel Kurchin and Eric Muckley and Lance Kavalsky and Vinay I. Hegde and Valentin Sulzer and Shang Zhu and Jiankun Pu and David Farina and Matthew Johnson and Dhairya Gandhi and Adarsh Dave and Hongyi Lin and Alan Edelman and Bharath Ramsundar and James Saal and Christopher Rackauckas and Viral Shah and Bryce Meredig and Venkatasubramanian Viswanathan},
  journal= {arXiv preprint arXiv:2011.04426},
  year   = {2022}
}

Comments

v1-3:4 pages, 1 figure, accepted to NeurIPS Climate Change and AI Workshop 2020, updating acknowledgements and citations v4: substantially updated content and author list, accepted to MRS Bulletin

R2 v1 2026-06-23T20:00:49.877Z