A database of experimentally measured lithium solid electrolyte conductivities evaluated with machine learning

Hargreaves, Cameron J.; Gaultois, Michael W.; Daniels, Luke M.; Watts, E. J.; Kurlin, Vitaliy; Moran, Michael; Dang, Yun; Morris, Rhun; Morscher, Alexandra; Thompson, Kate; Wright, Matthew A.; Prasad, Beluvalli-Eshwarappa; Blanc, Frédéric; Collins, Chris; Crawford, Catriona A.; Duff, Benjamin B.; Evans, Jae; Gamon, Jacinthe; Han, Guopeng; Leube, Bernhard T.; Niu, Hongjun; Perez, Arnaud J.; Robinson, Aris; Rogan, Oliver; Sharp, Paul M.; Shoko, Elvis; Sonni, Manel; THOMAS, WILLIAM; Vasylenko, Andrij; Wang, Lu; Rosseinsky, Matthew J.; Dyer, Matthew S.

doi:10.1038/s41524-022-00951-z

Cited by 17 publications

(14 citation statements)

References 55 publications

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“…Even though ML has been successfully applied for developing novel lithium-ion conductors − (e.g., Li 3.3 SnS 3.3 Cl 0.7 ) and oxide-ion conductors within the Ca-(Nb,Ta)-Bi-O system, , it still remains barely employed, most probably due to the limited number of suitable datasets available so far; therefore, few effective descriptors have been identified. In this sense, this Review proposes a potential dataset containing solid-state electrolytes based on tetrahedral units and different migration mechanisms that may be then screened by different ML methods with more descriptors related to site disorder and chemical bonding . Thus, it is expected that the applicability of AI and ML could increase as the computational performance and accessibility improve …”

Section: Discussionmentioning

confidence: 99%

“…In this sense, this Review proposes a potential dataset containing solid-state electrolytes based on tetrahedral units and different migration mechanisms that may be then screened by different ML methods with more descriptors related to site disorder and chemical bonding. 283 Thus, it is expected that the applicability of AI and ML could increase as the computational performance and accessibility improve. 282…”

Section: Design and Discovery Of New Oxide Ion Conductorsmentioning

confidence: 99%

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Oxide Ion-Conducting Materials Containing Tetrahedral Moieties: Structures and Conduction Mechanisms

2023

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This Review presents an overview from the perspective of tetrahedral chemistry on various oxide ion-conducting materials containing tetrahedral moieties which have received continuous growing attention as candidates for key components of various devices, including solid oxide fuel cells and oxygen sensors, due to the deformation and rotation flexibility of tetrahedral units facilitating oxide ion transport. Emphasis is placed on the structural and mechanistic features of various systems ranging from crystalline to amorphous materials, which include a variety of gallates, silicates, germanates, molybdates, tungstates, vanadates, aluminates, niobate, titanates, indium oxides, and the newly reported borates. They contain tetrahedral units in either isolated or linked manners forming different polyhedral dimensionality (0 to 3) with various defect properties and transport mechanisms. The development of oxide ion conductors containing tetrahedral moieties and the elucidation of the roles of tetrahedral units in oxide ion migration have demonstrated diverse opportunities for discovering superior electrolytes for solid oxide fuel cells and other related devices and provided useful clues for uncovering the key factors directing fast oxide ion conduction.

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Section: Discussionmentioning

confidence: 99%

Section: Design and Discovery Of New Oxide Ion Conductorsmentioning

confidence: 99%

Oxide Ion-Conducting Materials Containing Tetrahedral Moieties: Structures and Conduction Mechanisms

2023

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“…[116][117][118] Hargreaves et al introduced a meticulously curated dataset centered on lithium-ion conductors, along with their respective conductivities determined through impedance spectroscopy. [119] The compilation includes 820 entries sourced from 214 different references. Each entry includes details on the chemical makeup, a label given by experts based on structural characteristics, and the ionic conductivity at a particular temperature.…”

Section: Ionic Conductivitymentioning

confidence: 99%

Machine Learning‐Assisted Property Prediction of Solid‐State Electrolyte

Li,

Zhou,

et al. 2024

Advanced Energy Materials

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Machine learning (ML) exhibits substantial potential for predicting the properties of solid‐state electrolytes (SSEs). By integrating experimental or/and simulation data within ML frameworks, the discovery and development of advanced SSEs can be accelerated, ultimately facilitating their application in high‐end energy storage systems. This review commences with an introduction to the background of SSEs, including their explicit definition, comprehensive classification, intrinsic physical/chemical properties, underlying mechanisms governing their conductivity, challenges, and future developments. An in‐depth explanation of the ML methodology is also elucidated. Subsequently, the key factors that influence the performance of SSEs are summarized, including thermal expansion, modulus, diffusivity, ionic conductivity, reaction energy, migration barrier, band gap, and activation energy. Finally, it is offered perspectives on the design prerequisites for upcoming generations of SSEs, focusing on real‐time property prediction, multi‐property optimization, multiscale modeling, transfer learning, automation and high‐throughput experimentation, and synergistic optimization of full battery, all of which are crucial for accelerating the progress in SSEs. This review aims to guide the design and optimization of novel SSE materials for the practical realization of efficient and reliable SSEs in energy storage technologies.

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“…Machine learning (ML) methods have the potential to significantly enhance the accuracy of materials investigation because of their capacity for identifying complex patterns concealed underneath high-dimensional data. [108,[138][139][140][141][142][143] The ML on the basis of the materials database has been predictable to offer a complex nonlinear relationship between the property/function and structure/composition of the proposed materials such as the ionic conductor. [138,[144][145][146][147] A model was proposed for forecasting the ionic conductivity by ML based on currently available experimental data.…”

Section: Machine Learningmentioning

confidence: 99%

Evaluation of solid electrolytes: Development of conventional and interdisciplinary approaches

Tufail,

Zhai,

Khokar

et al. 2023

Interdisciplinary Materials

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Solid‐state lithium batteries (SSLBs) have received considerable attention due to their advantages in thermal stability, energy density, and safety. Solid electrolyte (SE) is a key component in developing high‐performance SSLBs. An in‐depth understanding of the intrinsic bulk and interfacial properties is imperative to achieve SEs with competitive performance. This review first introduces the traditional electrochemical approaches to evaluating the fundamental parameters of SEs, including the ionic and electronic conductivities, activation barrier, electrochemical stability, and diffusion coefficient. After that, the characterization techniques to evaluate the structural and chemical stability of SEs are reviewed. Further, emerging interdisciplinary visualization techniques for SEs and interfaces are highlighted, including synchrotron X‐ray tomography, ultrasonic scanning imaging, time‐of‐flight secondary‐ion mass spectrometry, and three‐dimensional stress mapping, which improve the understanding of electrochemical performance and failure mechanisms. In addition, the application of machine learning to accelerate the screening and development of novel SEs is introduced. This review article aims to provide an overview of advanced characterization from a broad physical chemistry view, inspiring innovative and interdisciplinary studies in solid‐state batteries.

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A database of experimentally measured lithium solid electrolyte conductivities evaluated with machine learning

Cited by 17 publications

References 55 publications

Oxide Ion-Conducting Materials Containing Tetrahedral Moieties: Structures and Conduction Mechanisms

Oxide Ion-Conducting Materials Containing Tetrahedral Moieties: Structures and Conduction Mechanisms

Machine Learning‐Assisted Property Prediction of Solid‐State Electrolyte

Evaluation of solid electrolytes: Development of conventional and interdisciplinary approaches

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