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Autori principali: LaBelle, Dmitri, Hu, Yong-Jie
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.13795
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author LaBelle, Dmitri
Hu, Yong-Jie
author_facet LaBelle, Dmitri
Hu, Yong-Jie
contents Phase-pure synthesis has been a major challenge for metal oxynitrides due to their sensitivity to synthesis conditions and the limited understanding of the underlying thermodynamics. The beta-phase tantalum oxynitride (beta-TaON), a promising material for applications in photocatalysis and energy storage, is particularly difficult to synthesize in a reproducible, phase-pure form. In this work, a computational thermodynamic model with experimental validation is presented to evaluate the phase-pure synthesis conditions for beta-TaON via ammonolysis reactions. The finite-temperature thermochemical properties of the reactant, product, and byproduct phases are predicted via first-principles calculations with the quasi-harmonic approach (QHA) as well as implemented from available thermodynamic databases. With the thermochemical properties, a thermodynamic model based on the CALculation of PHAse Diagrams (CALPAHD) approach is developed to assess the phase equilibria associated with the synthesis reactions and correspondingly predict the synthesis window for beta-TaON. A three-dimensional phase diagram is predicted as a function of gas composition and temperature, providing insights into optimal synthesis conditions. The computational predictions are further compared with available experimental data, offering a systematic framework for phase-pure beta-TaON synthesis.
format Preprint
id arxiv_https___arxiv_org_abs_2410_13795
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Predicting synthesis window of beta-TaON with thermodynamic modeling
LaBelle, Dmitri
Hu, Yong-Jie
Materials Science
Phase-pure synthesis has been a major challenge for metal oxynitrides due to their sensitivity to synthesis conditions and the limited understanding of the underlying thermodynamics. The beta-phase tantalum oxynitride (beta-TaON), a promising material for applications in photocatalysis and energy storage, is particularly difficult to synthesize in a reproducible, phase-pure form. In this work, a computational thermodynamic model with experimental validation is presented to evaluate the phase-pure synthesis conditions for beta-TaON via ammonolysis reactions. The finite-temperature thermochemical properties of the reactant, product, and byproduct phases are predicted via first-principles calculations with the quasi-harmonic approach (QHA) as well as implemented from available thermodynamic databases. With the thermochemical properties, a thermodynamic model based on the CALculation of PHAse Diagrams (CALPAHD) approach is developed to assess the phase equilibria associated with the synthesis reactions and correspondingly predict the synthesis window for beta-TaON. A three-dimensional phase diagram is predicted as a function of gas composition and temperature, providing insights into optimal synthesis conditions. The computational predictions are further compared with available experimental data, offering a systematic framework for phase-pure beta-TaON synthesis.
title Predicting synthesis window of beta-TaON with thermodynamic modeling
topic Materials Science
url https://arxiv.org/abs/2410.13795