Thermophysical Properties of a Uranium Nitride–Molybdenum-Tungsten Composite Fuel for Nuclear Thermal Propulsion

Joseph Schaeperkoetter; Scarlett Widgeon Paisner; Joshua White; Erofili Kardoulaki; Timothy Coons; Adrien Terricabras; Darrin Byler; Jhonathan Rosales; Kenneth McClellan

doi:dx.doi.org/10.1080/00295450.2025.2503674

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Thermophysical Properties of a Uranium Nitride–Molybdenum-Tungsten Composite Fuel for Nuclear Thermal Propulsion

Joseph Schaeperkoetter, Scarlett Widgeon Paisner, Joshua White, Erofili Kardoulaki, Timothy Coons, Adrien Terricabras, Darrin Byler, Jhonathan Rosales, Kenneth McClellan

Nuclear Technology / Volume 211 / Number 2S / October 2025 / Pages S29-S38

Research Articles / dx.doi.org/10.1080/00295450.2025.2503674

Received:October 29, 2024

Accepted:May 3, 2025

Published:November 3, 2025

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The thermal conductivity of a ceramic-metal composite consisting of 60 vol % uranium nitride incorporated into a molybdenum-tungsten matrix has been measured up to a temperature of 1200°C. Compositing nuclear fuel with refractory materials is considered a viable way to improve the thermal and mechanical properties of fuels, and more recently, has been investigated as a way to improve hydrogen compatibility in a nuclear thermal propulsion rocket reactor. Here, we demonstrate that high-density composites can be produced from direct current sintering and that the resulting thermal conductivity is improved compared to the pure.