Dislocation plasticity and detwinning under thermal stresses in nanotwinned Ag thin films

Wafer curvature measurements reported in literature for polycrystalline (often textured) and epitaxial fcc metal thin films on hard substrates show a characteristic “signature” in the stress-temperature evolution for either type of films. While epitaxial films reveal characteristic elastic – ideal p...

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Bibliographic Details
Published in:Acta materialia 2020-10, Vol.198, p.61-71
Main Authors: Kini, Maya K., Merola, Claudia, Breitbach, Benjamin, Klapproth, Dennis, Philippi, Bastian, Molin, Jean-Baptiste, Kirchlechner, Christoph, Dehm, Gerhard
Format: Article
Language:English
Subjects:
Coherent twin boundaries
Epitaxial nanotwinned fcc metal
Size effect
Thermomechanical deformation
Thin film plasticity
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Summary:Wafer curvature measurements reported in literature for polycrystalline (often textured) and epitaxial fcc metal thin films on hard substrates show a characteristic “signature” in the stress-temperature evolution for either type of films. While epitaxial films reveal characteristic elastic – ideal plastic deformation with no dislocation storage and highly repeatable cycles, polycrystalline films show considerable hardening upon cooling in addition to the relaxation by diffusional creep at elevated temperatures. In the present study, we study the deformation characteristics of an electron beam deposited epitaxial nanotwinned Ag on Si (111) substrate. The twin spacing λ of the nanotwinned Ag is controlled by suitable heat treatment and the “signature” thermomechanical deformation curves by wafer curvature measurements are recorded for twin spacings varying from 20 nm to 1 μm. Further, deformation is compared to other small scale deformation studies on fcc metals such as epitaxial bicrystal films, bicrystal micropillars containing a coherent twin boundary and nanotwinned micropillars. [Display omitted]
ISSN:1359-6454
1873-2453
DOI:10.1016/j.actamat.2020.07.056