First-principles study of structural, electronic, elastic and dielectric properties of RbLi2(NH2)3, LiH and LiNH2

Zhi Xin Bai; Wei Zeng; Bin Tang; Dai He Fan; Qi Jun Liu; Cheng Lu Jiang; Xiang Hui Chang

doi:10.1142/S0217979222500746

First-principles study of structural, electronic, elastic and dielectric properties of RbLi2(NH2)3, LiH and LiNH2

Zhi Xin Bai, Wei Zeng, Bin Tang, Dai He Fan, Qi Jun Liu, Cheng Lu Jiang, Xiang Hui Chang

School of Materials Sience and Engineering

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Based on the first-principles density-functional theory, the structural, electronic, elastic and dielectric properties of RbLi2(NH2)3, LiH and LiNH2 are calculated. We have analyzed the bond information in detail, where the atom Li in crystal is represented in ionic characteristics mostly. The small covalent bond behaviors are also captured between atom Li and others. The ionic characteristics with tiny covalent bonds are obviously beneficial to electrons for storage capacity and transferring. The mechanical properties of three crystals reveal that LiH has a strong resistance to deformation. It is predicted that LiH has a long service life as a battery in terms of deformation. The dielectric constant reveals that LiH has a better storage capacity than that of LiNH2. Additionally, LiH has low formation energy, where the harder substance is, the easier formation is.

Original language	English
Article number	2250074
Journal	International Journal of Modern Physics B
Volume	36
Issue number	15
DOIs	https://doi.org/10.1142/S0217979222500746
State	Published - 20 Jun 2022

Keywords

dielectric properties
elastic properties
electronic structure
First-principles calculation

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title = "First-principles study of structural, electronic, elastic and dielectric properties of RbLi2(NH2)3, LiH and LiNH2",

abstract = "Based on the first-principles density-functional theory, the structural, electronic, elastic and dielectric properties of RbLi2(NH2)3, LiH and LiNH2 are calculated. We have analyzed the bond information in detail, where the atom Li in crystal is represented in ionic characteristics mostly. The small covalent bond behaviors are also captured between atom Li and others. The ionic characteristics with tiny covalent bonds are obviously beneficial to electrons for storage capacity and transferring. The mechanical properties of three crystals reveal that LiH has a strong resistance to deformation. It is predicted that LiH has a long service life as a battery in terms of deformation. The dielectric constant reveals that LiH has a better storage capacity than that of LiNH2. Additionally, LiH has low formation energy, where the harder substance is, the easier formation is.",

keywords = "dielectric properties, elastic properties, electronic structure, First-principles calculation",

author = "Bai, {Zhi Xin} and Wei Zeng and Bin Tang and Fan, {Dai He} and Liu, {Qi Jun} and Jiang, {Cheng Lu} and Chang, {Xiang Hui}",

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T1 - First-principles study of structural, electronic, elastic and dielectric properties of RbLi2(NH2)3, LiH and LiNH2

AU - Bai, Zhi Xin

AU - Zeng, Wei

AU - Tang, Bin

AU - Fan, Dai He

AU - Liu, Qi Jun

AU - Jiang, Cheng Lu

AU - Chang, Xiang Hui

PY - 2022/6/20

Y1 - 2022/6/20

N2 - Based on the first-principles density-functional theory, the structural, electronic, elastic and dielectric properties of RbLi2(NH2)3, LiH and LiNH2 are calculated. We have analyzed the bond information in detail, where the atom Li in crystal is represented in ionic characteristics mostly. The small covalent bond behaviors are also captured between atom Li and others. The ionic characteristics with tiny covalent bonds are obviously beneficial to electrons for storage capacity and transferring. The mechanical properties of three crystals reveal that LiH has a strong resistance to deformation. It is predicted that LiH has a long service life as a battery in terms of deformation. The dielectric constant reveals that LiH has a better storage capacity than that of LiNH2. Additionally, LiH has low formation energy, where the harder substance is, the easier formation is.

AB - Based on the first-principles density-functional theory, the structural, electronic, elastic and dielectric properties of RbLi2(NH2)3, LiH and LiNH2 are calculated. We have analyzed the bond information in detail, where the atom Li in crystal is represented in ionic characteristics mostly. The small covalent bond behaviors are also captured between atom Li and others. The ionic characteristics with tiny covalent bonds are obviously beneficial to electrons for storage capacity and transferring. The mechanical properties of three crystals reveal that LiH has a strong resistance to deformation. It is predicted that LiH has a long service life as a battery in terms of deformation. The dielectric constant reveals that LiH has a better storage capacity than that of LiNH2. Additionally, LiH has low formation energy, where the harder substance is, the easier formation is.

KW - dielectric properties

KW - elastic properties

KW - electronic structure

KW - First-principles calculation

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DO - 10.1142/S0217979222500746

M3 - 文章

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SN - 0217-9792

VL - 36

JO - International Journal of Modern Physics B

JF - International Journal of Modern Physics B

IS - 15

M1 - 2250074

ER -

First-principles study of structural, electronic, elastic and dielectric properties of RbLi2(NH2)3, LiH and LiNH2

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Keywords

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