Litcius/Paper detail

A new mechanism for void-cascade interaction from nondestructive depth-resolved atomic-scale measurements of ion irradiation–induced defects in Fe

Sahil Agarwal, Maciej Oskar Liedke, A. C. L. Jones, E. Reed, Aaron A. Kohnert, Blas P. Uberuaga, Yongqiang Wang, J. Cooper, Djamel Kaoumi, Nan Li, R. Auguste, Peter Hosemann, Laurent Capolungo, Danny J. Edwards, Maik Butterling, Eric Hirschmann, A. Wagner, F. A. Selim

2020Science Advances51 citationsDOIOpen Access PDF

Abstract

The nondestructive investigation of single vacancies and vacancy clusters in ion-irradiated samples requires a depth-resolved probe with atomic sensitivity to defects. The recent development of short-pulsed positron beams provides such a probe. Here, we combine depth-resolved Doppler broadening and positron annihilation lifetime spectroscopies to identify vacancy clusters in ion-irradiated Fe and measure their density as a function of depth. Despite large concentrations of dislocations and voids in the pristine samples, positron annihilation measurements uncovered the structure of vacancy clusters and the change in their size and density with irradiation dose. When combined with transmission electron microscopy measurements, the study demonstrates an association between the increase in the density of small vacancy clusters with irradiation and a remarkable reduction in the size of large voids. This, previously unknown, mechanism for the interaction of cascade damage with voids in ion-irradiated materials is a consequence of the high porosity of the initial microstructure.

Topics & Concepts

Vacancy defectIrradiationVoid (composites)Materials sciencePositron annihilation spectroscopyIonTransmission electron microscopyMicrostructureMolecular physicsAtomic unitsCascadeDoppler broadeningAtomic physicsPorosityElectronPositronPositron annihilationChemistrySpectral lineNanotechnologyCrystallographyNuclear physicsPhysicsComposite materialAstronomyChromatographyQuantum mechanicsOrganic chemistryMuon and positron interactions and applicationsFusion materials and technologiesIon-surface interactions and analysis