# Superionic UO2: A Model Anharmonic Crystalline Material

**Authors:** Hao Zhang, Xinyi Wang, Alexandros Chremos, and Jack F. Douglas

arXiv: 1902.02858 · 2019-05-22

## TL;DR

This study investigates the superionic properties of UO2, revealing how cooperative ionic motion influences high-temperature conductivity and providing models to predict its behavior for energy applications.

## Contribution

The paper introduces a quantitative description of ion diffusion and structural relaxation in superionic UO2 using generalized activated transport and entropy-based models.

## Key findings

- Non-Arrhenius diffusion behavior described by string model
- Excess entropy correlates with collective ion motion
- Distinct temperature dependence of interfacial mobility in ionic materials

## Abstract

Crystalline materials at elevated temperatures and pressures can exhibit properties more reminiscent of simple liquids than ideal crystalline materials. Superionic crystalline materials having a liquid-like conductivity {\sigma} are particularly interesting for battery, fuel cell, and other energy applications, and we study UO2 as a prototypical superionic material since this material is widely studied given its commercial importance as reactor fuel. Using molecular dynamics, we first investigate basic thermodynamic and structural properties. We then quantify structural relaxation, dynamic heterogeneity, and average ions mobility. We find that the non-Arrhenius diffusion and structural relaxation time of this prototypical superionic material can be quantitatively described in terms of a generalized activated transport model ('string model') in which the activation energy varies in direct proportion to the average string length. Our transport data can also be described equally well by an Adam-Gibbs model in which the excess entropy density of the crystalline material is estimated from specific heat and thermal expansion data, consistent with the average scale of string-like collective motion scaling inversely with the excess entropy of the crystal. Strong differences in the temperature dependence of the interfacial mobility from non-ionic materials are observed, and we suggest that this difference is due to the relatively high cohesive interaction of ionic materials. In summary, the study of superionic UO2 provides insight into the role of cooperative motion in enhancing ion mobility in ionic materials and offers design principles for the development of new superionic materials for use in diverse energy applications.

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Source: https://tomesphere.com/paper/1902.02858