English

Physics-informed tritium fuel cycle modelling workflow for fusion reactors

Plasma Physics 2026-04-17 v1 Applied Physics

Abstract

In this work, we present a multi-fidelity, physics-informed framework for tritium fuel cycle modelling based on the open-source PathSim/PathView platform. Three complementary modelling approaches are demonstrated within a unified dynamic simulation environment. First, a zero-dimensional residence time model is used to reproduce the fuel cycle behaviour of an ARC-class fusion power plant, providing a baseline system-level description. Second, an intermediate-fidelity component model based on coupled one-dimensional ordinary differential equations is developed to describe tritium mass transfer in a liquid metal bubble column reactor and validated against published literature before integration into the full fuel cycle. Finally, high-fidelity multi-dimensional tritium transport models implemented using the finite element code FESTIM are coupled directly to the system model, enabling the inclusion of multi-dimensional effects, material interfaces, and complex transport phenomena. This work demonstrates how fuel cycle components of varying physical fidelity can be combined consistently within a single, open-source framework. The proposed approach enables more physically grounded fuel cycle analyses while retaining the flexibility required for system-level studies and provides a foundation for future integration with neutronics, fluid dynamics, and surrogate modelling tools.

Keywords

Cite

@article{arxiv.2603.25751,
  title  = {Physics-informed tritium fuel cycle modelling workflow for fusion reactors},
  author = {Rémi Delaporte-Mathurin and Ross MacDonald and James Dark and Milan Rother and Tasnim Zulfiqar and Kevin B. Woller},
  journal= {arXiv preprint arXiv:2603.25751},
  year   = {2026}
}
R2 v1 2026-07-01T11:39:42.684Z