Online in-situ X-ray diffraction setup for structural modification studies during swift heavy ion irradiation

TL;DR

This paper introduces ALIX, an in-situ X-ray diffraction setup for real-time study of structural changes in materials under swift heavy ion irradiation, revealing material-specific radiation responses and phase transition mechanisms.

Contribution

The paper presents a novel in-situ X-ray diffractometer setup enabling simultaneous irradiation and diffraction studies during swift heavy ion exposure.

Findings

MgO is radiation-resistant to high electronic excitations.

SrTiO3 undergoes amorphization during irradiation.

Single impact model explains phase transition mechanism.

Abstract

The high energy density of electronic excitations due to the impact of swift heavy ions can induce structural modifications in materials. We present a X-ray diffractometer called ALIX, which has been set up at the low-energy IRRSUD beamline of the GANIL facility, to allow the study of structural modification kinetics as a function of the ion fluence. The X-ray setup has been modified and optimized to enable irradiation by swift heavy ions simultaneously to X-ray pattern recording. We present the capability of ALIX to perform simultaneous irradiation - diffraction by using energy discrimination between X-rays from diffraction and from ion-target interaction. To illustrate its potential, results of sequential or simultaneous irradiation - diffraction are presented in this article to show radiation effects on the structural properties of ceramics. Phase transition kinetics have been studied during xenon ion irradiation of polycrystalline MgO and SrTiO3. We have observed that MgO oxide is radiation-resistant to high electronic excitations, contrary to the high sensitivity of SrTiO3, which exhibits transition from the crystalline to the amorphous state during irradiation. By interpreting the amorphization kinetics of SrTiO3, defect overlapping models are discussed as well as latent track characteristics. Together with a transmission electron microscopy study, we conclude that a single impact model describes the phase transition mechanism.