Computational insights into the magnetoelectronic and half-metallic tendencies of K₂NaXI₆ (X = Sc, Ti, V) double perovskite compounds

Double perovskites have gained prominence in materials science due to their unique properties and diverse applications. Our study explores the magnetoelectronic characteristics of the K₂NaXI₆ series, where X is Sc, Ti, or V. We employed density functional theory (DFT) calculations using the PBEsol f...

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Vydané v:	Journal of materials research Ročník 40; číslo 5; s. 718 - 726
Hlavní autori:	Kheir Allah, Mohammed, Bensaid, Djillali, Mokaddem, Khadidja, Bensafa, Imad Khaled, Nour-Eddine Benkhettou, Bencherif, Kaddour
Médium:	Journal Article
Jazyk:	English
Vydavateľské údaje:	Cham Springer International Publishing 14.03.2025 Springer Nature B.V
Predmet:	Alternative energy sources Applied and Technical Physics Approximation Biomaterials Bonding Charge distribution Chemistry and Materials Science Crystal structure Density functional theory Electron density Electron spin Electron transport Energy conversion Energy gap Inorganic Chemistry Iodine Magnetic properties Materials Engineering Materials Science Nanotechnology Optical properties Perovskites Potassium Titanium Vanadium Perovskites Ferromagnetic Spintronic Metal-insulator transition Computation/computing
ISSN:	0884-2914, 2044-5326
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Shrnutí:	Double perovskites have gained prominence in materials science due to their unique properties and diverse applications. Our study explores the magnetoelectronic characteristics of the K₂NaXI₆ series, where X is Sc, Ti, or V. We employed density functional theory (DFT) calculations using the PBEsol functional and the KTB-mBJ method to predict magnetic properties accurately. Our results revealed distinct electronic behaviors within the series. K₂NaScI₆ exhibited semiconducting properties with a direct band gap at the Γ point, suggesting potential for light-emitting and absorbing applications. Conversely, K₂NaTiI₆ and K₂NaVI₆ displayed half-metallic behavior with band gaps in the minority spin channel, indicating potential for spin-dependent electronic transport. To further understand chemical bonding and interactions, we conducted Bader charge analysis and electron density calculations. These investigations provide comprehensive insights into the charge distribution and bonding characteristics of these promising double perovskite materials. Graphic abstract
Bibliografia:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14
ISSN:	0884-2914 2044-5326
DOI:	10.1557/s43578-025-01530-w