Developing Reduced Order Models for Gas Bubble Formation in Irradiated Metals Using Integrated Phase Field Modeling and Koopman Operator Theory

Author

John M. Eggemeyer V, Clemson UniversityFollow

Date of Award

5-2025

Document Type

Thesis

Degree Name

Master of Engineering (ME)

Department

Mechanical Engineering

Committee Chair/Advisor

Cheng Sun

Committee Member

Enrique Martinez Saez

Committee Member

Umesh Vaidya

Abstract

Irradiation damage in materials is prevalent in nuclear components, posing significant risks in the safety and reliability of nuclear reactors. Phase field models offer a versatile framework for modeling irradiation damage in materials at mesoscales. Such high fidelity method has been used to model the formation of fission gas bubbles superlattice, a microstructure array occurs at certain irradiation conditions (dose, dose-rate, and temperature). To overcome the high computational cost of phase field modeling, Koopman operator theory is applied to create reduced order models, allowing for instantaneous simulations of fission gas bubble behaviors. These low fidelity models are integrated into machine learning methods to predict the formation window of gas bubble superlattice, and then validated by the high fidelity phase field models and experiments. In this thesis, phase field models of irradiation damage along with dynamic mode decomposition (DMD) method were developed in reducing the computational costs of high fidelity simulations.

Recommended Citation

Eggemeyer, John M. V, "Developing Reduced Order Models for Gas Bubble Formation in Irradiated Metals Using Integrated Phase Field Modeling and Koopman Operator Theory" (2025). All Theses. 4512.
https://open.clemson.edu/all_theses/4512