Ab initio insight into the physical properties of MgXH3 (X = Co, Cu, Ni) lead-free perovskite for hydrogen storage application

Renewable energy systems are vital for a sustainable future, where solid-state hydrogen storage can play a crucial role. Perovskite hydride materials have attracted the scientific community for hydrogen storage applications. The current work focuses on the theoretical study using density functional...

Full description

Saved in:
Bibliographic Details
Main Authors: Rehman Z., Rehman M.A., Rehman B., Sikiru S., Qureshi S., Ali E.M., Awais M., Amjad M., Iqbal I., Rafique A., Bibi S.
Other Authors: 57225362130
Format: Article
Published: Springer 2024
Subjects:
DFT
Tags: Add Tag
No Tags, Be the first to tag this record!
id my.uniten.dspace-33976
record_format dspace
spelling my.uniten.dspace-339762024-10-14T11:17:33Z Ab initio insight into the physical properties of MgXH3 (X = Co, Cu, Ni) lead-free perovskite for hydrogen storage application Rehman Z. Rehman M.A. Rehman B. Sikiru S. Qureshi S. Ali E.M. Awais M. Amjad M. Iqbal I. Rafique A. Bibi S. 57225362130 57204391658 57355281700 57211063469 56247296300 57004451100 57940545000 57976351200 58832018200 57219255410 56400623400 DFT Elastic constants Electronic structure Hydrogen storage Perovskite hydrides Calcium Compounds Hydrogen Oxides Thermodynamics calcium derivative hydrogen oxide perovskite thermodynamics Renewable energy systems are vital for a sustainable future, where solid-state hydrogen storage can play a crucial role. Perovskite hydride materials have attracted the scientific community for hydrogen storage applications. The current work focuses on the theoretical study using density functional theory (DFT) to evaluate the characteristics of MgXH3 (X = Co, Cu, Ni) hydrides. The structural, vibrational, electronic, mechanical, thermodynamic, and hydrogen storage properties of these hydrides were investigated. The equilibrium lattice parameters were calculated using the Birch-Murnaghan equation of state-to-energy volume curves. The elastic constants (Cij) and relevant parameters, such as Born criteria, were calculated to confirm the mechanical stability of the hydrides. The Cauchy pressure (C p) revealed brittle or ductile behavior. The outcomes of the Pugh ratio, Poisson ratio, and anisotropy were also calculated and discussed. The absence of negative lattice vibrational frequencies in phonon dispersion confirmed the lattice�s dynamic stability. The heat capacity curves of thermodynamic properties revealed that hydrides can conduct thermal energy. The metallic character and ample interatomic distances of hydrides were confirmed by the band structure and population analysis, which confirmed that hydrides can conduct electrical energy and adsorb hydrogen. The density of state (DOS) and partial DOS unveiled the role of specific atoms in the DOS of the crystal. The calculated gravimetric hydrogen storage capacity of MgCoH3, MgCuH3, and MgNiH3 hydrides was 3.64, 3.32, and 3.49wt%, respectively. Our results provide a deeper understanding of its potential for hydrogen storage applications through a detailed analysis of MgXH3 (X = Co, Cu, Ni) perovskite hydride material. � 2023, The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature. Final 2024-10-14T03:17:33Z 2024-10-14T03:17:33Z 2023 Article 10.1007/s11356-023-30279-0 2-s2.0-85174490401 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85174490401&doi=10.1007%2fs11356-023-30279-0&partnerID=40&md5=80b6a41a2c2af86932ab430ab1df7d2d https://irepository.uniten.edu.my/handle/123456789/33976 30 53 113889 113902 Springer Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic DFT
Elastic constants
Electronic structure
Hydrogen storage
Perovskite hydrides
Calcium Compounds
Hydrogen
Oxides
Thermodynamics
calcium derivative
hydrogen
oxide
perovskite
thermodynamics
spellingShingle DFT
Elastic constants
Electronic structure
Hydrogen storage
Perovskite hydrides
Calcium Compounds
Hydrogen
Oxides
Thermodynamics
calcium derivative
hydrogen
oxide
perovskite
thermodynamics
Rehman Z.
Rehman M.A.
Rehman B.
Sikiru S.
Qureshi S.
Ali E.M.
Awais M.
Amjad M.
Iqbal I.
Rafique A.
Bibi S.
Ab initio insight into the physical properties of MgXH3 (X = Co, Cu, Ni) lead-free perovskite for hydrogen storage application
description Renewable energy systems are vital for a sustainable future, where solid-state hydrogen storage can play a crucial role. Perovskite hydride materials have attracted the scientific community for hydrogen storage applications. The current work focuses on the theoretical study using density functional theory (DFT) to evaluate the characteristics of MgXH3 (X = Co, Cu, Ni) hydrides. The structural, vibrational, electronic, mechanical, thermodynamic, and hydrogen storage properties of these hydrides were investigated. The equilibrium lattice parameters were calculated using the Birch-Murnaghan equation of state-to-energy volume curves. The elastic constants (Cij) and relevant parameters, such as Born criteria, were calculated to confirm the mechanical stability of the hydrides. The Cauchy pressure (C p) revealed brittle or ductile behavior. The outcomes of the Pugh ratio, Poisson ratio, and anisotropy were also calculated and discussed. The absence of negative lattice vibrational frequencies in phonon dispersion confirmed the lattice�s dynamic stability. The heat capacity curves of thermodynamic properties revealed that hydrides can conduct thermal energy. The metallic character and ample interatomic distances of hydrides were confirmed by the band structure and population analysis, which confirmed that hydrides can conduct electrical energy and adsorb hydrogen. The density of state (DOS) and partial DOS unveiled the role of specific atoms in the DOS of the crystal. The calculated gravimetric hydrogen storage capacity of MgCoH3, MgCuH3, and MgNiH3 hydrides was 3.64, 3.32, and 3.49wt%, respectively. Our results provide a deeper understanding of its potential for hydrogen storage applications through a detailed analysis of MgXH3 (X = Co, Cu, Ni) perovskite hydride material. � 2023, The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.
author2 57225362130
author_facet 57225362130
Rehman Z.
Rehman M.A.
Rehman B.
Sikiru S.
Qureshi S.
Ali E.M.
Awais M.
Amjad M.
Iqbal I.
Rafique A.
Bibi S.
format Article
author Rehman Z.
Rehman M.A.
Rehman B.
Sikiru S.
Qureshi S.
Ali E.M.
Awais M.
Amjad M.
Iqbal I.
Rafique A.
Bibi S.
author_sort Rehman Z.
title Ab initio insight into the physical properties of MgXH3 (X = Co, Cu, Ni) lead-free perovskite for hydrogen storage application
title_short Ab initio insight into the physical properties of MgXH3 (X = Co, Cu, Ni) lead-free perovskite for hydrogen storage application
title_full Ab initio insight into the physical properties of MgXH3 (X = Co, Cu, Ni) lead-free perovskite for hydrogen storage application
title_fullStr Ab initio insight into the physical properties of MgXH3 (X = Co, Cu, Ni) lead-free perovskite for hydrogen storage application
title_full_unstemmed Ab initio insight into the physical properties of MgXH3 (X = Co, Cu, Ni) lead-free perovskite for hydrogen storage application
title_sort ab initio insight into the physical properties of mgxh3 (x = co, cu, ni) lead-free perovskite for hydrogen storage application
publisher Springer
publishDate 2024
_version_ 1814061035758288896
score 13.214268