Persistence of ultrafast atomic diffusion paths in recrystallizing ultrafine grained Ni
Prokoshkina D., Klinger L., Moros A., Wilde G., Rabkin E., Divinski S.
Research article (journal) | Peer reviewedAbstract
Tracer self-diffusion is investigated in ultrafine grained Ni prepared by high pressure torsion. Under identical diffusion annealing conditions the ultrafine grained structure of less pure Ni remains stable, while recrystallization and subsequent grain growth occur in high purity Ni. Nevertheless, qualitatively similar ultrafast diffusion rates are measured in the samples of both purity levels. A model explaining retention of deformation-induced ultrafast diffusion paths in recrystallized Ni in terms of solute redistribution in front of the moving boundary is suggested.
Details about the publication
Journal: Scripta Materialia
Volume: 101
Issue: null
Page range: 91-94
Status: Published
Release year: 2015
Language in which the publication is written: English
Link to the full text: http://www.scopus.com/inward/record.url?partnerID=HzOxMe3b&scp=84924617201&origin=inward
Keywords: High pressure torsion (HPT); Nickel Diffusion; Recrystallization; Segregation
Authors from the University of Münster
| Divinskyi, Sergii | Professorship of Materials Physics (Prof. Wilde) |
| Moros, Anna | Institute of Materials Physics |
| Prokoshkina, Daria | Institute of Materials Physics |
| Wilde, Gerhard | Professorship of Materials Physics (Prof. Wilde) |