First principle study of LiXS2(X= Ga, In) as cathode materials for Li ion batteries

Rao, Fengya; Ning, Fanghua; Jiang, Liwei; Zeng, Xierong; Wu, Musheng; Xu, Bo; Ouyang, Chuying

doi:10.1088/1674-1056/25/2/028202

Cited by 3 publications

(1 citation statement)

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“…[16] Recently, many 2D materials have been proposed theoretically as a promising candidate for applications in LIBs. [17][18][19] Multiscale computation methods, including first-principles calcu-lation, molecular dynamics simulation, phase field simulation, finite element, and machine learning, can be applied in discovery and design of new electrode materials. [12] As a relatively new family of monolayer materials, 2D transition metal carbides and nitrides with a general formula of M n+1 X n , namely MXenes, show promising applications as anode materials for LIBs, in view of their excellent electron conduction and high charge/discharge rates.…”

Section: Introductionmentioning

confidence: 99%

Two-dimensional CrP₂ with high specific capacity and fast charge rate for lithium-ion battery

2023

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The electrode material is regarded as one of the key factors that determine the performance of lithium-ion batteries (LIBs). However, it is still a challenge to search for an anode material with large capacity, low diffusion barrier, and good stability. In the present work, two new CrP2 monolayers (Pmmn-CrP2 and Pmma-CrP2) are predicted by means of first principles swarm structure search. Our study shows that both the two CrP2 monolayers have high dynamical and thermal stability, as well as excellent electron conductivity. Additionally, Pmmn-CrP2 exhibits a remarkably high storage capacity of 705 mA h g-1 for Li, meanwhile the diffusion energy barrier of Li on the surface of this monolayer is 0.21 eV, ensuring it as a high-performance anode material for LIBs. We hope that our study will inspire researchers to search for new-type 2D transition metal phosphides for the electrode materials of LIBs.

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Section: Introductionmentioning

confidence: 99%

Two-dimensional CrP₂ with high specific capacity and fast charge rate for lithium-ion battery

2023

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First-principles identification of spinel CaCo2O4 as a promising cathode material for Ca-ion batteries

et al. 2018

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Anion Charge and Lattice Volume Maps for Searching Lithium Superionic Conductors

Zhu

2020

Chem. Mater.

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The effects of anion charge and lattice volume (lithium− anion bond length) on lithium ion migration have been investigated by utilizing the density functional theory calculations combined with the anion sublattice models. It is found that anion charge and lattice volume have great impacts on the activation energy barrier of lithium ion migration, which is validated by some reported sulfides. For the tetrahedrally occupied lithium, the less negative the anion charge is, the lower the migration energy barrier is likely to be. While for the octahedrally occupied lithium, the more negative anion charge is, the lower migration energy barrier is. Based on the full understandings of the anion sublattice model, general design strategies for developing lithium superionic conductors were proposed. Adjusting the electronegativity difference between the anion element and the nonmobile cation element by selecting the most suitable nonmobile cation element without changing the crystal structure framework can achieve low activation energy barriers for lithium ion migration. For the desired lithium superionic conductors with tetrahedrally occupied lithium, the fine nonmobile cation elements should give preference to those elements located at the right top of the periodic table of elements with large electronegativities. For the lithium superionic conductors with octahedrally occupied lithium, the fine nonmobile cation elements should give preferences to the elements located at the left bottom of the periodic table with small electronegativities.

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First principle study of LiXS₂(X= Ga, In) as cathode materials for Li ion batteries

Cited by 3 publications

References 61 publications

Two-dimensional CrP₂ with high specific capacity and fast charge rate for lithium-ion battery

Two-dimensional CrP₂ with high specific capacity and fast charge rate for lithium-ion battery

First-principles identification of spinel CaCo2O4 as a promising cathode material for Ca-ion batteries

Anion Charge and Lattice Volume Maps for Searching Lithium Superionic Conductors

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First principle study of LiXS2(X= Ga, In) as cathode materials for Li ion batteries

Cited by 3 publications

References 61 publications

Two-dimensional CrP2 with high specific capacity and fast charge rate for lithium-ion battery

Two-dimensional CrP2 with high specific capacity and fast charge rate for lithium-ion battery

First-principles identification of spinel CaCo2O4 as a promising cathode material for Ca-ion batteries

Anion Charge and Lattice Volume Maps for Searching Lithium Superionic Conductors

Contact Info

Product

Resources

About

First principle study of LiXS₂(X= Ga, In) as cathode materials for Li ion batteries

Two-dimensional CrP₂ with high specific capacity and fast charge rate for lithium-ion battery

Two-dimensional CrP₂ with high specific capacity and fast charge rate for lithium-ion battery