Data‐Driven Materials Exploration for Li‐Ion Conductive Ceramics by Exhaustive and Informatics‐Aided Computations

Nakayama, Masanobu; Kanamori, Kenta; Nakano, K.; Jalem, Randy; Takeuchi, Ichiro; Yamasaki, Hiroyuki

doi:10.1002/tcr.201800129

Cited by 42 publications

(41 citation statements)

References 65 publications

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“…Using less expensive computational techniques allows the generation of a larger quantity of training data. For example, Nakayama et al trained PLS and GBR models on the Li migration energy in 400 Li‐containing compounds computed using bond‐valence force fields (BVFFs). While statistically more robust, it is unclear whether the source of the training data—BVFF calculations—are sufficiently accurate to yield useful predictions, i.e., data quantity may be sufficient, but data quality is in question.…”

Section: Applicationmentioning

confidence: 99%

A Critical Review of Machine Learning of Energy Materials

Chen

Zuo

et al. 2020

Advanced Energy Materials

398

281

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Machine learning (ML) is rapidly revolutionizing many fields and is starting to change landscapes for physics and chemistry. With its ability to solve complex tasks autonomously, ML is being exploited as a radically new way to help find material correlations, understand materials chemistry, and accelerate the discovery of materials. Here, an in‐depth review of the application of ML to energy materials, including rechargeable alkali‐ion batteries, photovoltaics, catalysts, thermoelectrics, piezoelectrics, and superconductors, is presented. A conceptual framework is first provided for ML in materials science, with a broad overview of different ML techniques as well as best practices. This is followed by a critical discussion of how ML is applied in energy materials. This review is concluded with the perspectives on major challenges and opportunities in this exciting field.

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Section: Applicationmentioning

confidence: 99%

A Critical Review of Machine Learning of Energy Materials

Chen

Zuo

et al. 2020

Advanced Energy Materials

398

281

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“…Data resources such as the Materials Project [ 34 ] can be used to assist in the detection of materials that can be considered as SSEs through machine learning. [ 35,36,37 ] Machine learning is applied to filter and select the materials based on their properties. Computational methods such as DFT and AIMD simulations can then be used to determine further properties and the diffusion coefficient of the filtered materials.…”

Section: Ionic Conductivity Of Solid‐state Electrolytesmentioning

confidence: 99%

“…Computational methods such as DFT and AIMD simulations can then be used to determine further properties and the diffusion coefficient of the filtered materials. [ 35 ] The need for access to a large amount of meaningful, high‐quality data is the main problem of studies based on machine learning; [ 36 ] however, this will improve in the future as the potential of this approach is realized.…”

Section: Ionic Conductivity Of Solid‐state Electrolytesmentioning

confidence: 99%

Shaping the Future of Solid‐State Electrolytes through Computational Modeling

et al. 2020

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Advances and progress in computational research that aims to understand and improve solid‐state electrolytes (SSEs) are outlined. One of the main challenges in the development of all‐solid‐state batteries is the design of new SSEs with high ion diffusivity that maintain chemical and phase stability and thereby provide a wide electrochemical stability window. Solving this problem requires a deep understanding of the diffusion mechanism and properties of the SSEs. A second important challenge is the development of an understanding of the interface between the SSE and the electrode. The role of molecular simulations and modeling in dealing with these challenges is discussed, with reference to examples in the literature. The methods used and issues considered in recent years are highlighted. Finally, a brief outlook about the future of modeling in studying solid‐state battery technology is presented.

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“…3,4 Solid electrolytes have lower ionic conductivities than liquid electrolytes; to address this, methods to prepare solid electrolyte materials with high ionic conductivities are actively explored. [5][6][7] Recently, NASICON-type oxide-based solid electrolytes attracted considerable interest due to their high Li-ion conductivity. 8,9 Li 1.3 Al 0.3 Ti 1.7 (PO 4 ) 3 (LATP), prepared based on LiTi 2 (PO 4 ) 3 (LTP), 10,11 is a well-known NASICON-type solid electrolyte that builds on the advantages of LTP, such as high conductivity and stability under ambient conditions.…”

Section: Introductionmentioning

confidence: 99%