Thermal Energy Transport in Oxide Nuclear Fuel

TL;DR

This review discusses the challenges and advances in understanding thermal energy transport in oxide nuclear fuels, focusing on uranium dioxide and thorium dioxide, especially under irradiation conditions affecting reactor safety and performance.

Contribution

It provides a comprehensive overview of recent computational and experimental research on phonon transport and defect effects in nuclear oxide fuels, highlighting progress and remaining challenges.

Findings

Defects from fission damage scatter phonons, degrading thermal transport.

Ion irradiation studies serve as surrogates for fission damage effects.

Progress in modeling and experimental validation of mesoscale thermal transport.

Abstract

To efficiently capture the energy of the nuclear bond, advanced nuclear reactor concepts seek solid fuels that must withstand unprecedented temperature and radiation extremes. In these advanced fuels, thermal energy transport under irradiation is directly related to reactor performance as well as reactor safety. The science of thermal transport in nuclear fuel is a grand challenge due to both computational and experimental complexities. Here, we provide a comprehensive review of thermal transport research on two actinide oxides: one currently in use in commercial nuclear reactors, uranium dioxide (UO2), and one advanced fuel candidate material, thorium dioxide (ThO2). In both materials, heat is carried by lattice waves or phonons. Crystalline defects caused by fission events effectively scatter phonons and lead to a degradation in fuel performance over time. Bolstered by new computational and experimental tools, researchers are now developing the foundational work necessary to accurately model and ultimately control thermal transport in advanced nuclear fuel. We begin by reviewing research aimed at understanding thermal transport in perfect single crystals. The absence of defects enables studies that focus on the fundamental aspects of phonon transport. Next, we review research that targets defect generation and evolution. Here, the focus is on ion irradiation studies used as surrogates for damage caused by fission products. We end this review with a discussion of modeling and experimental efforts directed at predicting and validating mesoscale thermal transport in the presence of irradiation defects. While efforts into these research areas have been robust, challenging work remains in developing holistic tools to capture and predict thermal energy transport across widely varying environmental conditions.