Saved in:
Bibliographic Details
Main Authors: Azam, Sikander, Rafiq, Qaiser, Elsharkawy, Eman Ramadan, Khan, Muhammad Tahir, El-Bahy, Salah M., Khan, Wilayat, Khan, Saleem Ayaz
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.07290
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909532675899392
author Azam, Sikander
Rafiq, Qaiser
Elsharkawy, Eman Ramadan
Khan, Muhammad Tahir
El-Bahy, Salah M.
Khan, Wilayat
Khan, Saleem Ayaz
author_facet Azam, Sikander
Rafiq, Qaiser
Elsharkawy, Eman Ramadan
Khan, Muhammad Tahir
El-Bahy, Salah M.
Khan, Wilayat
Khan, Saleem Ayaz
contents This study uses the density functional theory (DFT) approach with GGA-PBE to assess the effect of substituting alkali metals in Rb$_{2}$CaH and Cs-doped Rb$_{2}$CaH$_{4}$ on their hydrogen storage potential. To address the challenges associated with predicting accurate electronic properties in materials containing heavier elements such as cesium, spin-orbit coupling (SOC) effects have been incorporated into our calculations. The mechanical robustness of both Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$, as demonstrated by their mechanical properties, highlights these materials as promising candidates due to their stability in hydrogen storage applications. Anisotropic factors show that all materials exhibit anisotropy, suggesting a directional dependency in their properties. The Pugh ratio indicates that Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$ are brittle materials. Based on the calculated band gap, the electronic band structure analysis, conducted using both HSE06 and GGA-PBE, shows that Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$ are wide-bandgap materials. Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$ exhibit the highest optical conductivity, absorption coefficient, and energy loss function among optoelectronic materials, emphasizing their superior absorption and electron transfer capabilities. The hydrogen storage capacity has been evaluated for practical applications; Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$ show the highest gravimetric and volumetric capacities.
format Preprint
id arxiv_https___arxiv_org_abs_2503_07290
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle First-principles investigation of Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$: unveiling their potential for hydrogen storage through mechanical and optoelectronic properties
Azam, Sikander
Rafiq, Qaiser
Elsharkawy, Eman Ramadan
Khan, Muhammad Tahir
El-Bahy, Salah M.
Khan, Wilayat
Khan, Saleem Ayaz
Materials Science
Computational Physics
This study uses the density functional theory (DFT) approach with GGA-PBE to assess the effect of substituting alkali metals in Rb$_{2}$CaH and Cs-doped Rb$_{2}$CaH$_{4}$ on their hydrogen storage potential. To address the challenges associated with predicting accurate electronic properties in materials containing heavier elements such as cesium, spin-orbit coupling (SOC) effects have been incorporated into our calculations. The mechanical robustness of both Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$, as demonstrated by their mechanical properties, highlights these materials as promising candidates due to their stability in hydrogen storage applications. Anisotropic factors show that all materials exhibit anisotropy, suggesting a directional dependency in their properties. The Pugh ratio indicates that Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$ are brittle materials. Based on the calculated band gap, the electronic band structure analysis, conducted using both HSE06 and GGA-PBE, shows that Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$ are wide-bandgap materials. Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$ exhibit the highest optical conductivity, absorption coefficient, and energy loss function among optoelectronic materials, emphasizing their superior absorption and electron transfer capabilities. The hydrogen storage capacity has been evaluated for practical applications; Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$ show the highest gravimetric and volumetric capacities.
title First-principles investigation of Rb$_{2}$CaH$_{4}$ and Cs-doped Rb$_{2}$CaH$_{4}$: unveiling their potential for hydrogen storage through mechanical and optoelectronic properties
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2503.07290