Software for Evaluating Long-Range Electrostatic Interactions Based on the Ewald Summation and Its Application to Electrochemical Energy Storage Materials

Shi, Wei; He, Bing; Pu, Bowei; Ren, Yuan; Avdeev, Maxim; Shi, Siqi

doi:10.1021/acs.jpca.2c02591

J. Phys. Chem. A

2022

DOI: 10.1021/acs.jpca.2c02591

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Software for Evaluating Long-Range Electrostatic Interactions Based on the Ewald Summation and Its Application to Electrochemical Energy Storage Materials

Wei Shi

Bing He

Bowei Pu

et al.

Abstract: Electrochemical characteristics such as open-circuit voltage and ionic conductivity of electrochemical energy storage materials are easily affected, typically negatively, by mobile ion/vacancy ordering. Ordered phases can be identified based on the lattice gas model and electrostatic energy screening. However, the evaluation of long-range electrostatic energy is not straightforward because of the conditional convergence. The Ewald method decomposes the electrostatic energy into a real space part and a reciproc… Show more

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Cited by 4 publications

References 37 publications

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Advancements in Battery Materials: Bio-Based and Mineral Fillers for Next-Generation Solid Polymer Electrolytes

Subhani,

Khademolqorani,

Banitaba

et al. 2024

ACS Appl. Mater. Interfaces

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The state-of-the-art all-solid-state batteries are expected to surpass conventional flammable Li-ion batteries, offering high energy density and safety in an ultrathin and lightweight solvent-free polymeric electrolyte (SPE). Nevertheless, there is an urgent need to boost the room-temperature ionic conductivity and interfacial charge transport of the SPEs to approach practical all-solid-state devices. Accordingly, loading filler grains into SPEs has been well-documented as a versatile strategy, promoting the overall electrochemical performance. In this era, using natural resources to extract filler additives has attracted tremendous attention to curb fossil fuel dependency. Also, there is a growing preference for materials that impose minimal environmental harm, are sustainable, and exhibit environmentally friendly characteristics. Therefore, mineral and biobased fillers, as natural-based additives, are strong candidates to replace traditional petroleum-based synthetic materials. Herein, we conduct a systematic investigation into the ion-transport mechanisms and fundamental properties of the filler-loaded SPEs. Additionally, recent advances in SPE architectures through embedding mineral and biobased fillers, as well as their hybrid compositions, are focused. Finally, the downsides and future directions are highlighted to facilitate further development and research toward revitalizing rechargeable battery-related technology. Overall, efficient methods for modifying SPEs through the use of natural resource organic and inorganic fillers are discussed, and technological advancements and related challenges are emphasized. Following the provided rational solutions to overcome major obstacles faced by SPEs, we hope to meet the demands of a greener future.

show abstract

Advancements in Battery Materials: Bio-Based and Mineral Fillers for Next-Generation Solid Polymer Electrolytes

Subhani,

Khademolqorani,

Banitaba

et al. 2024

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

show abstract

Unlocking the secrets of ideal fast ion conductors for all-solid-state batteries

Sau,

Takagi,

Ikeshoji

et al. 2024

Commun Mater

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All-solid-state batteries (ASSBs) are promising alternatives to conventional lithium-ion batteries. ASSBs consist of solid-fast-ion-conducting electrolytes and electrodes that offer improved energy density, battery safety, specific power, and fast-charging capability. Despite decades of intensive research, only a few have high ionic conductivity at ambient temperature. Developing fast ion-conducting materials requires both synthesis of high-conducting materials and a fundamental understanding of ion transport mechanisms. However, this is challenging due to wide variations of the ionic conductivity, even within the same class of materials, indicating the strong influence of structural modifications on ion transport. This Review discusses three selected material classes, namely layered oxides, polyhedral connections, and cluster anion types, as promising fast ion conductors. Emphasis is placed on the inherent challenges and the role of the framework structure on mobile ion conduction. We elucidate strategies to address these challenges by leveraging theoretical frameworks and insights from materials science.

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Portraying the ionic transport and stability window of solid electrolytes by incorporating bond valence-Ewald with dynamically determined decomposition methods

Ren

Liu

et al. 2022

Applied Physics Letters

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Designing inorganic solid electrolytes (ISEs) with both excellent electrochemical stability and high ionic conductivity is an important research direction for all-solid-state batteries. However, due to the electronic conduction of hierarchical decomposition products, there is an imbalance between the ionic transport and electrochemical stability window of the ISEs. Here, we propose a computational approach that incorporates bond valence-Ewald energy analysis and dynamically determined decomposition pathway to portray the competing relationship between ionic transport and stable electrochemical window in solid electrolytes. Following this, we explain the high ionic conductivity and wide electrochemical stability window of Li–Si–B–S solid electrolytes, which features shared corner and edge from tetrahedral SiS4/BS4. Our approach is not only applicable to efficiently characterize the previously reported inorganic solid electrolytes but also expected to accelerate the discovery of more systems.

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Software for Evaluating Long-Range Electrostatic Interactions Based on the Ewald Summation and Its Application to Electrochemical Energy Storage Materials

Cited by 4 publications

References 37 publications

Advancements in Battery Materials: Bio-Based and Mineral Fillers for Next-Generation Solid Polymer Electrolytes

Advancements in Battery Materials: Bio-Based and Mineral Fillers for Next-Generation Solid Polymer Electrolytes

Unlocking the secrets of ideal fast ion conductors for all-solid-state batteries

Portraying the ionic transport and stability window of solid electrolytes by incorporating bond valence-Ewald with dynamically determined decomposition methods

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