Litcius/Paper detail

Microstructural complexity and dimensional changes in heavily irradiated zirconium

Andrew R. Warwick, Max Boleininger, S. L. Dudarev

2021Physical Review Materials17 citationsDOIOpen Access PDF

Abstract

Using atomistic simulations based on the creation-relaxation algorithm, we explore the evolution of microstructure in irradiated zirconium over a broad range of radiation exposure. In agreement with experimental observations, we find that at relatively low temperatures, microstructure evolves towards an asymptotic dynamic steady state forming at doses close to 1 dpa. Simulations show the spontaneous formation of $a$-type interstitial dislocation loops, gradually transforming into an $a$-type extended dislocation network and giving rise to macroscopic anisotropic dimensional changes in a textured material. A fully developed $a$-type interstitial/vacancy and $c$-type vacancy dislocation microstructure corresponds to the highest degree of irradiation growth anisotropy and vanishingly small volumetric swelling of the material.

Topics & Concepts

Materials scienceMicrostructureZirconiumVacancy defectAnisotropyDislocationIrradiationRelaxation (psychology)SwellingRange (aeronautics)Condensed matter physicsCrystallographyComposite materialMetallurgyOpticsNuclear physicsPhysicsSocial psychologyChemistryPsychologyNuclear Materials and PropertiesNuclear materials and radiation effectsFusion materials and technologies