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Plasticity response of 6H-SiC and related isostructural materials to nanoindentation: Slip vs densification

Lookup NU author(s): Emeritus Professor Trevor Page


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As part of a programme investigating whether slip (by dislocation motion at some critical resolved shear stress) or densification (by structural collapse at some critical hydrostatic pressure) dominates the plastic deformation response of open-crystal-structured ceramics having the diamond, zinc blende or simply-related structures, transmission electron microscopy (TEM) and high resolution scanning electron microscopy (HRSEM) are being used to characterize the deformation structures in, and around, nanoindentations made over a range of loads in single crystal samples of Si, Ge, SiC and various III-V and II-VI compound semiconductors. Since SiC is believed to lie close to the boundary between those materials which slip and those which densify as primary plasticity responses to contact with Vickers and Berkovich indenters, this part of the study has focused on establishing the deformation mechanisms of 6H-SiC during nanoindentation. TEM of nanoindentations in (0001) 6H-SiC samples has established that dislocation slip is indeed the sole mechanism of plastic deformation from the nucleation of a few dislocation loops - at or near the theoretical strength - to extensive dislocation plasticity. Also, HRSEM observations have revealed slip steps of limited extent in 6H-SiC samples with more extensive slip steps arrays found in all the other compounds. By contrast, both Si and Ge show evidence of heavily deformed - and sometimes extruded - material believed to be a characteristic of structural collapse accommodating at least some part of the indentation strain before any dislocation slip occurs.

Publication metadata

Author(s): Page TF, Riester L, Hainsworth SV

Publication type: Article

Publication status: Published

Journal: Materials Research Society Symposium Proceedings

Year: 1998

Volume: 522

Pages: 113-118

ISSN (print): 0272-9172

ISSN (electronic): 1946-4274

Publisher: Materials Research Society