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Main Authors: Rosander, Petter, Fransson, Erik, Österbacka, Nicklas, Erhart, Paul, Wahnström, Göran
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2409.16161
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author Rosander, Petter
Fransson, Erik
Österbacka, Nicklas
Erhart, Paul
Wahnström, Göran
author_facet Rosander, Petter
Fransson, Erik
Österbacka, Nicklas
Erhart, Paul
Wahnström, Göran
contents Raman spectroscopy is a widely used experimental technique to study the vibrational properties of solids. Atomic scale simulations can be used to predict such spectra, but trustworthy studies at finite temperatures are challenging, mainly due to the requirement of accurate and computationally efficient models for the dielectric susceptibility. Here, we have made use of molecular dynamics (MD) simulations together with a density functional theory (DFT) based model for the dielectric susceptibility to determine the Raman spectrum of barium zirconate, BaZrO$_3$ (BZO), a well-studied oxide perovskite. At ambient conditions, where the system is cubic, we find excellent agreement with experimentally measured Raman spectra. Our study establishes that the relatively sharp spectra seen experimentally are due to second-order scattering. At higher pressures, where BZO is tetragonal, all first-order Raman active modes are identified. Additionally, slightly below the phase transition, in the cubic phase, a broad "central Raman peak" appears. The origin of this type of peak is controversial and extensively debated in connection to the dynamics of the halide perovskites. Here, we show that it is also present in a "hard" oxide perovskite, and it originates from the highly overdamped R-tilt mode in the cubic structure.
format Preprint
id arxiv_https___arxiv_org_abs_2409_16161
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Untangling the Raman spectrum of cubic and tetragonal BaZrO$_3$
Rosander, Petter
Fransson, Erik
Österbacka, Nicklas
Erhart, Paul
Wahnström, Göran
Materials Science
Raman spectroscopy is a widely used experimental technique to study the vibrational properties of solids. Atomic scale simulations can be used to predict such spectra, but trustworthy studies at finite temperatures are challenging, mainly due to the requirement of accurate and computationally efficient models for the dielectric susceptibility. Here, we have made use of molecular dynamics (MD) simulations together with a density functional theory (DFT) based model for the dielectric susceptibility to determine the Raman spectrum of barium zirconate, BaZrO$_3$ (BZO), a well-studied oxide perovskite. At ambient conditions, where the system is cubic, we find excellent agreement with experimentally measured Raman spectra. Our study establishes that the relatively sharp spectra seen experimentally are due to second-order scattering. At higher pressures, where BZO is tetragonal, all first-order Raman active modes are identified. Additionally, slightly below the phase transition, in the cubic phase, a broad "central Raman peak" appears. The origin of this type of peak is controversial and extensively debated in connection to the dynamics of the halide perovskites. Here, we show that it is also present in a "hard" oxide perovskite, and it originates from the highly overdamped R-tilt mode in the cubic structure.
title Untangling the Raman spectrum of cubic and tetragonal BaZrO$_3$
topic Materials Science
url https://arxiv.org/abs/2409.16161