A facility for thermo-mechanical characterization of fusion magnet materials during cryogenic ion irradiation

TL;DR

This paper introduces a novel cryogenic ion irradiation facility that combines transient grating spectroscopy with in-situ measurements to study the thermo-mechanical degradation of fusion magnet materials under extreme conditions.

Contribution

The development of an innovative in-situ measurement platform that simultaneously assesses thermal and mechanical properties during cryogenic ion irradiation is the paper's key novelty.

Findings

Thermal diffusivity of copper nearly halved during irradiation.

Surface acoustic wave speed remained stable at approximately 2162 m/s.

The facility enables real-time monitoring of material degradation under fusion-relevant conditions.

Abstract

Commercial fusion power plants demand magnet materials that retain structural integrity and thermal conductivity while operating under the bombardment of energetic neutrons at cryogenic temperatures. Understanding how thermo-mechanical properties evolve under such extreme loads is crucial for selecting materials with high radiation tolerance and predictable failure mechanisms. Presented here is a facility that combines cryogenic transient grating spectroscopy (TGS) with simultaneous ion irradiation, enabling in-situ measurements of thermal diffusivity and surface acoustic wave (SAW) frequency spectra. Employing copper as a benchmark material, an irradiation was performed at 30 K with 12.4 MeV $\text{Cu}^{6+}$ ions producing a final fluence of $1.9 \times 10^{17}$ ions/m$^2$. Over the irradiation period, thermal diffusivity nearly halved from an initial value of $1.2 \times 10^{-4}$ $\text{m}^2/\text{s}$ while SAW speed did not show significant change, maintaining a value of $2162\pm18$ m/s. Given its real-time monitoring capability and the numerous candidate materials that remain uncharacterized under fusion magnet operating conditions, this facility is poised to deliver new scientific insights into fusion magnet material degradation trends, contributing to improved design criteria and operational certainty for forthcoming fusion power plants.