Andrew A. Prudil scite author profile

This article describes a phase-field model for an isothermal multicomponent, multiphase system which avoids implicit interfacial energy contributions by starting from a grand potential formulation. A method is developed for incorporating arbitrary forms of the equilibrium thermodynamic potentials in all phases to determine an explicit relationship between chemical potentials and species concentrations. The model incorporates variable densities between adjacent phases, defect migration, and dependence of internal pressure on object dimensions ranging from the macro- to nanoscale. A demonstrative simulation of an overpressurized nanoscopic intragranular bubble in nuclear fuel migrating to a grain boundary under kinetically limited vacancy diffusion is shown.

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Development and testing of the FAST fuel performance code: Normal operating conditions (Part 1)

Prudil

Lewis

Chan

et al. 2015

Nuclear Engineering and Design

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Network percolation using a two-species included phase model to predict fission gas accommodation and venting

Prudil

Thomas

Welland

2019

Journal of Nuclear Materials

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Andrew A. Prudil

Fully coupled multiphysics modeling of enhanced thermal conductivity UO 2 –BeO fuel performance in a light water reactor

Multiphysics coupled modeling of light water reactor fuel performance

Linearization-based method for solving a multicomponent diffusion phase-field model with arbitrary solution thermodynamics

Development and testing of the FAST fuel performance code: Normal operating conditions (Part 1)

Network percolation using a two-species included phase model to predict fission gas accommodation and venting

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