# Beta-PtO2: Phononic, thermodynamic, and elastic properties derived from   first-principles calculations

**Authors:** Quan Chen, Wei Li, Yong Yang

arXiv: 1905.03550 · 2019-05-10

## TL;DR

This study uses first-principles calculations to comprehensively analyze the phononic, thermodynamic, and elastic properties of beta-PtO2, providing new insights into its stability and mechanical behavior under pressure.

## Contribution

It is the first systematic investigation of beta-PtO2's thermodynamic and elastic properties using first-principles methods, including pressure effects on phonons and elastic moduli.

## Key findings

- Optical phonon frequencies increase with pressure, matching experimental data.
- Bulk modulus increases linearly with pressure, shear modulus remains nearly constant.
- Elastic stiffness coefficients C44, C55, and C66 are key to shear modulus variation.

## Abstract

Beta-PtO2 is a useful transition metal dioxide, but its fundamental thermodynamic and elastic properties remain unexplored. Using first-principles calculations, we systematically studied the structure, phonon, thermodynamic and elastic properties of beta-PtO2. The lattice dynamics and structural stability of beta-PtO2 under pressure were studied using the phonon spectra and vibrational density of states. The vibrational frequencies of the optical modes of beta-PtO2 increase with elevating pressure; this result is comparable with the available experimental data. Then, the heat capacities and their pressure responses were determined based on the phonon calculations. The pressure dependence of the Debye temperature was studied, and the results are compared in two distinct aspects. The elastic moduli of beta-PtO2 were estimated through the Voigt-Reuss-Hill approximation. The bulk modulus of beta-PtO2 increases linearly with pressure, but the shear modulus is nearly independent of pressure. Our study revealed that the elastic stiffness coefficients C44, C55 and C66 play a primary role in the slow variation of the shear modulus.

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Source: https://tomesphere.com/paper/1905.03550