Revealing atomic-scale vacancy-solute interaction in nickel

It is widely accepted that the different types of crystalline imperfections, such as vacancies or dislocations, greatly influence a material's physical and mechanical properties. However, imaging individual vacancies in solids and revealing their atomic neighborhood remains one of the frontiers of microscopy and microanalysis. Here, we study a creep-deformed binary Ni-2 at.% Ta alloy. Atom probe tomography reveals a random distribution of Ta. Field ion microscopy, with contrast interpretation supported by density-functional theory and time-of-flight mass spectrometry, evidences a positive correlation of Ta with vacancies, supporting positive solute-vacancy interactions previously predicted by atomistic simulations. (C) 2021 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

Automated summary

Different types of crystalline imperfections greatly influence a material's properties, with imaging individual vacancies in solids being a frontier in microscopy. A study on a creep-deformed Ni-2 at.% Ta alloy showed a positive correlation of Ta with vacancies, in line with atomistic simulations.