Ab initio calculations of the electronic structure for Mn2+-doped YAlO3 crystals

S. Piskunov; I. Isakoviea; M. Putnina; A. I. Popov

Ab initio calculations of the electronic structure for Mn²⁺-doped YAlO3 crystals

Laboratory of Computer Modeling of Electronic Structure of Solids, Institute of Solid State Physics
Laboratory of Kinetics in Self-Organizing Systems, Institute of Solid State Physics

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

2 Citations (Scopus)

Abstract

The electronic structure of Mn2+ ion substituted for the host Y atom in orthorhombic bulk YAlO3 crystals has been calculated by means of hybrid exchange-correlation functional HSE within density functional theory. The supercell approach has been used to simulate in Pbnm YAlO3 crystal the point defects, Mn-dopant and compensated the F+ center (oxygen vacancy with one trapped electron), to make unit cell neutral. Large 2 × 2 × 2 supercells of 160 atoms allow us to simulate substitutional point defect with concentration of about 3 %. Mn²⁺ions substi-tuting for host Y form covalent Mn-O bonds, in opposite to the mostly ionic Y-O bond. The F⁺center inserted to compensate the Mn²⁺dopant in YAlO3 affects the electronic structure of a host material inducing three defect energy levels in the band gap.

Original language	English
Pages (from-to)	1365-1370
Number of pages	6
Journal	Fizika Nizkikh Temperatur
Volume	46
Issue number	12
Publication status	Published - Dec 2020

Keywords

ab initio modeling
Electronic structure
Mn-dopant
Substitutional point defects

Cite this

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title = "Ab initio calculations of the electronic structure for Mn2+-doped YAlO3 crystals",

abstract = "The electronic structure of Mn2+ ion substituted for the host Y atom in orthorhombic bulk YAlO3 crystals has been calculated by means of hybrid exchange-correlation functional HSE within density functional theory. The supercell approach has been used to simulate in Pbnm YAlO3 crystal the point defects, Mn-dopant and compensated the F+ center (oxygen vacancy with one trapped electron), to make unit cell neutral. Large 2 × 2 × 2 supercells of 160 atoms allow us to simulate substitutional point defect with concentration of about 3 \%. Mn2+ions substi-tuting for host Y form covalent Mn-O bonds, in opposite to the mostly ionic Y-O bond. The F+center inserted to compensate the Mn2+dopant in YAlO3 affects the electronic structure of a host material inducing three defect energy levels in the band gap.",

keywords = "ab initio modeling, Electronic structure, Mn-dopant, Substitutional point defects",

author = "S. Piskunov and I. Isakoviea and M. Putnina and Popov, \{A. I.\}",

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T1 - Ab initio calculations of the electronic structure for Mn2+-doped YAlO3 crystals

AU - Piskunov, S.

AU - Isakoviea, I.

AU - Putnina, M.

AU - Popov, A. I.

PY - 2020/12

Y1 - 2020/12

N2 - The electronic structure of Mn2+ ion substituted for the host Y atom in orthorhombic bulk YAlO3 crystals has been calculated by means of hybrid exchange-correlation functional HSE within density functional theory. The supercell approach has been used to simulate in Pbnm YAlO3 crystal the point defects, Mn-dopant and compensated the F+ center (oxygen vacancy with one trapped electron), to make unit cell neutral. Large 2 × 2 × 2 supercells of 160 atoms allow us to simulate substitutional point defect with concentration of about 3 %. Mn2+ions substi-tuting for host Y form covalent Mn-O bonds, in opposite to the mostly ionic Y-O bond. The F+center inserted to compensate the Mn2+dopant in YAlO3 affects the electronic structure of a host material inducing three defect energy levels in the band gap.

AB - The electronic structure of Mn2+ ion substituted for the host Y atom in orthorhombic bulk YAlO3 crystals has been calculated by means of hybrid exchange-correlation functional HSE within density functional theory. The supercell approach has been used to simulate in Pbnm YAlO3 crystal the point defects, Mn-dopant and compensated the F+ center (oxygen vacancy with one trapped electron), to make unit cell neutral. Large 2 × 2 × 2 supercells of 160 atoms allow us to simulate substitutional point defect with concentration of about 3 %. Mn2+ions substi-tuting for host Y form covalent Mn-O bonds, in opposite to the mostly ionic Y-O bond. The F+center inserted to compensate the Mn2+dopant in YAlO3 affects the electronic structure of a host material inducing three defect energy levels in the band gap.

KW - ab initio modeling

KW - Electronic structure

KW - Mn-dopant

KW - Substitutional point defects

UR - https://www.scopus.com/pages/publications/85100302429

M3 - Article

AN - SCOPUS:85100302429

SN - 0132-6414

VL - 46

SP - 1365

EP - 1370

JO - Fizika Nizkikh Temperatur

JF - Fizika Nizkikh Temperatur

IS - 12

ER -

Ab initio calculations of the electronic structure for Mn²⁺-doped YAlO3 crystals

Abstract

Keywords

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