TY - JOUR
T1 - Pushing the boundaries of lithium battery research with atomistic modelling on different scales
AU - Morgan, Lucy M.
AU - Mercer, Michael P.
AU - Bhandari, Arihant
AU - Peng, Chao
AU - Islam, Mazharul M.
AU - Yang, Hui
AU - Holland, Julian
AU - Coles, Samuel W.
AU - Sharpe, Ryan
AU - Walsh, Aron
AU - Morgan, Benjamin J.
AU - Kramer, Denis
AU - Saiful Islam, M.
AU - Hoster, Harry E.
AU - Edge, Jacqueline Sophie
AU - Skylaris, Chris Kriton
N1 - Publisher Copyright:
© 2021 The Author(s). Published by IOP Publishing Ltd
PY - 2022/1
Y1 - 2022/1
N2 - Computational modelling is a vital tool in the research of batteries and their component materials. Atomistic models are key to building truly physics-based models of batteries and form the foundation of the multiscale modelling chain, leading to more robust and predictive models. These models can be applied to fundamental research questions with high predictive accuracy. For example, they can be used to predict new behaviour not currently accessible by experiment, for reasons of cost, safety, or throughput. Atomistic models are useful for quantifying and evaluating trends in experimental data, explaining structure-property relationships, and informing materials design strategies and libraries. In this review, we showcase the most prominent atomistic modelling methods and their application to electrode materials, liquid and solid electrolyte materials, and their interfaces, highlighting the diverse range of battery properties that can be investigated. Furthermore, we link atomistic modelling to experimental data and higher scale models such as continuum and control models. We also provide a critical discussion on the outlook of these materials and the main challenges for future battery research.
AB - Computational modelling is a vital tool in the research of batteries and their component materials. Atomistic models are key to building truly physics-based models of batteries and form the foundation of the multiscale modelling chain, leading to more robust and predictive models. These models can be applied to fundamental research questions with high predictive accuracy. For example, they can be used to predict new behaviour not currently accessible by experiment, for reasons of cost, safety, or throughput. Atomistic models are useful for quantifying and evaluating trends in experimental data, explaining structure-property relationships, and informing materials design strategies and libraries. In this review, we showcase the most prominent atomistic modelling methods and their application to electrode materials, liquid and solid electrolyte materials, and their interfaces, highlighting the diverse range of battery properties that can be investigated. Furthermore, we link atomistic modelling to experimental data and higher scale models such as continuum and control models. We also provide a critical discussion on the outlook of these materials and the main challenges for future battery research.
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U2 - 10.1088/2516-1083/ac3894
DO - 10.1088/2516-1083/ac3894
M3 - Review article
AN - SCOPUS:85136570881
SN - 2516-1083
VL - 4
JO - Progress in Energy
JF - Progress in Energy
IS - 1
M1 - 012002
ER -