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Main Authors: Rushchanskii, Konstantin Z., Medulych, Mykola, Liubachko, Vitalii, Vysochanskii, Yulian M.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.14179
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author Rushchanskii, Konstantin Z.
Medulych, Mykola
Liubachko, Vitalii
Vysochanskii, Yulian M.
author_facet Rushchanskii, Konstantin Z.
Medulych, Mykola
Liubachko, Vitalii
Vysochanskii, Yulian M.
contents For the Sn$_2$P$_2$S$_6$ crystalline compound with a rich temperature--pressure phase diagram that contains the ferroelectric phase, semiconductor-to-metal transition, and superconductive state, \mbox{\textit{ab initio}} molecular dynamics calculations were performed on a single unit cell and on a superstructure using an evolutionary algorithm in combination with density functional theory calculations to study structural transformations resulting from rearrangements in chemical bonds under pressure. The structure models of the pressure-induced lowest energy phases in the molecular Sn$_2$P$_2$S$_6$ crystal demonstrate the possibility of space-arranged chains or rings of P$_2$S$_6$ molecules. Pressure can break P-P bonds of P$_2$S$_6$ molecules, causing one of the phosphorous atoms to displace into the sulfur-formed octahedron and providing another phosphorous atom into an octahedral coordination with two tin atoms and four sulfur atoms. The results of the modeling correlate with the gradual rise of deviation of the pressure dependence of the unit cell volume of the Sn$_2$P$_2$S$_6$ structure, as determined by X-ray diffraction experiments, from the dependence calculated with the Birch-Murnaghan equation of state. It also reveals toroidally ordered local dipoles in the centrosymmetric phase, which may be related to the previously observed superconductivity in the high-pressure metallic phase of Sn$_2$P$_2$S$_6$.
format Preprint
id arxiv_https___arxiv_org_abs_2408_14179
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Pressure-induced toroidal order in molecular Sn$_2$P$_2$S$_6$ ferroelectrics
Rushchanskii, Konstantin Z.
Medulych, Mykola
Liubachko, Vitalii
Vysochanskii, Yulian M.
Materials Science
For the Sn$_2$P$_2$S$_6$ crystalline compound with a rich temperature--pressure phase diagram that contains the ferroelectric phase, semiconductor-to-metal transition, and superconductive state, \mbox{\textit{ab initio}} molecular dynamics calculations were performed on a single unit cell and on a superstructure using an evolutionary algorithm in combination with density functional theory calculations to study structural transformations resulting from rearrangements in chemical bonds under pressure. The structure models of the pressure-induced lowest energy phases in the molecular Sn$_2$P$_2$S$_6$ crystal demonstrate the possibility of space-arranged chains or rings of P$_2$S$_6$ molecules. Pressure can break P-P bonds of P$_2$S$_6$ molecules, causing one of the phosphorous atoms to displace into the sulfur-formed octahedron and providing another phosphorous atom into an octahedral coordination with two tin atoms and four sulfur atoms. The results of the modeling correlate with the gradual rise of deviation of the pressure dependence of the unit cell volume of the Sn$_2$P$_2$S$_6$ structure, as determined by X-ray diffraction experiments, from the dependence calculated with the Birch-Murnaghan equation of state. It also reveals toroidally ordered local dipoles in the centrosymmetric phase, which may be related to the previously observed superconductivity in the high-pressure metallic phase of Sn$_2$P$_2$S$_6$.
title Pressure-induced toroidal order in molecular Sn$_2$P$_2$S$_6$ ferroelectrics
topic Materials Science
url https://arxiv.org/abs/2408.14179