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Main Authors: Datta, Sujoy, Singh, Prashant
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.05206
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author Datta, Sujoy
Singh, Prashant
author_facet Datta, Sujoy
Singh, Prashant
contents The future of spintronic and semiconductor applications demands materials with tailored electronic and magnetic properties. This study uses density functional theory to investigate the electronic structure of the half-metallic compound Mn$_{4}$Al$_{11}$ under uniaxial strain and in its Ge-substituted derivatives. Strain analysis shows that although the half-metallic band-gap collapses under strain beyond $-2\%$, the ferrimagnetic character remains stable. Ge substitution at six inequivalent Al-sites in Mn$_{4}$Al$_{11}$ results in varying degrees of metallicity and magnetic properties. Substitution at Al$=(000)$ induces a metal-to-insulator transition with an indirect semiconducting gap of $0.14~ eV$. Bonding and hybridization analysis reveals that local Mn-Al interactions due to Ge substitution significantly modify the local electronic structure, causing both electronic and magnetic phase transitions. This work highlights the effectiveness of substitutional doping in tuning half-metallicity and magnetic properties in inorganic solids, enabling the design of materials for future technological applications.
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institution arXiv
publishDate 2025
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spellingShingle Doping Induced Magnetic and Electronic phase Transition in Ferrimagnetic Half-metallic Mn$_{4}$Al$_{11}$ Compound
Datta, Sujoy
Singh, Prashant
Materials Science
The future of spintronic and semiconductor applications demands materials with tailored electronic and magnetic properties. This study uses density functional theory to investigate the electronic structure of the half-metallic compound Mn$_{4}$Al$_{11}$ under uniaxial strain and in its Ge-substituted derivatives. Strain analysis shows that although the half-metallic band-gap collapses under strain beyond $-2\%$, the ferrimagnetic character remains stable. Ge substitution at six inequivalent Al-sites in Mn$_{4}$Al$_{11}$ results in varying degrees of metallicity and magnetic properties. Substitution at Al$=(000)$ induces a metal-to-insulator transition with an indirect semiconducting gap of $0.14~ eV$. Bonding and hybridization analysis reveals that local Mn-Al interactions due to Ge substitution significantly modify the local electronic structure, causing both electronic and magnetic phase transitions. This work highlights the effectiveness of substitutional doping in tuning half-metallicity and magnetic properties in inorganic solids, enabling the design of materials for future technological applications.
title Doping Induced Magnetic and Electronic phase Transition in Ferrimagnetic Half-metallic Mn$_{4}$Al$_{11}$ Compound
topic Materials Science
url https://arxiv.org/abs/2507.05206