Thickness-dependent phase transformation in nanoindented germanium thin films

D. J. Oliver; J. E. Bradby; J. S. Williams; M. V. Swain; P. Munroe

doi:10.1088/0957-4484/19/47/475709

Thickness-dependent phase transformation in nanoindented germanium thin films

D. J. Oliver, J. E. Bradby, J. S. Williams, M. V. Swain, P. Munroe

Research output: Contribution to journal › Article › peer-review

25 Citations (Scopus)

Abstract

We investigate the mechanical response of 50-600 nm epitaxial Ge films on a Si substrate using nanoindentation with a nominally spherical (R≈4.3 νm) diamond tip. The inelastic deformation mechanism is found to depend critically on the film thickness. Sub-100 nm Ge films deform by pressure-induced phase transformation, whereas thicker films deform only by shear-induced dislocation slip and twinning. Nanoindentation fracture response is similarly dependent on film thickness. Elastic stress modelling shows that differing stress modes vary in their spatial distribution, and consequently the film thickness governs the stress state in the film, in conjunction with the radius of the nanoindenter tip. This opens the prospect of tailoring the contact response of Ge and related materials in thin film form by varying film thickness and indenter radius.

Original language	English
Article number	475709
Journal	Nanotechnology
Volume	19
Issue number	47
DOIs	https://doi.org/10.1088/0957-4484/19/47/475709
Publication status	Published - 26 Nov 2008

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title = "Thickness-dependent phase transformation in nanoindented germanium thin films",

abstract = "We investigate the mechanical response of 50-600 nm epitaxial Ge films on a Si substrate using nanoindentation with a nominally spherical (R≈4.3 νm) diamond tip. The inelastic deformation mechanism is found to depend critically on the film thickness. Sub-100 nm Ge films deform by pressure-induced phase transformation, whereas thicker films deform only by shear-induced dislocation slip and twinning. Nanoindentation fracture response is similarly dependent on film thickness. Elastic stress modelling shows that differing stress modes vary in their spatial distribution, and consequently the film thickness governs the stress state in the film, in conjunction with the radius of the nanoindenter tip. This opens the prospect of tailoring the contact response of Ge and related materials in thin film form by varying film thickness and indenter radius.",

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AU - Oliver, D. J.

AU - Bradby, J. E.

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AU - Swain, M. V.

AU - Munroe, P.

PY - 2008/11/26

Y1 - 2008/11/26

N2 - We investigate the mechanical response of 50-600 nm epitaxial Ge films on a Si substrate using nanoindentation with a nominally spherical (R≈4.3 νm) diamond tip. The inelastic deformation mechanism is found to depend critically on the film thickness. Sub-100 nm Ge films deform by pressure-induced phase transformation, whereas thicker films deform only by shear-induced dislocation slip and twinning. Nanoindentation fracture response is similarly dependent on film thickness. Elastic stress modelling shows that differing stress modes vary in their spatial distribution, and consequently the film thickness governs the stress state in the film, in conjunction with the radius of the nanoindenter tip. This opens the prospect of tailoring the contact response of Ge and related materials in thin film form by varying film thickness and indenter radius.

AB - We investigate the mechanical response of 50-600 nm epitaxial Ge films on a Si substrate using nanoindentation with a nominally spherical (R≈4.3 νm) diamond tip. The inelastic deformation mechanism is found to depend critically on the film thickness. Sub-100 nm Ge films deform by pressure-induced phase transformation, whereas thicker films deform only by shear-induced dislocation slip and twinning. Nanoindentation fracture response is similarly dependent on film thickness. Elastic stress modelling shows that differing stress modes vary in their spatial distribution, and consequently the film thickness governs the stress state in the film, in conjunction with the radius of the nanoindenter tip. This opens the prospect of tailoring the contact response of Ge and related materials in thin film form by varying film thickness and indenter radius.

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DO - 10.1088/0957-4484/19/47/475709

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SN - 0957-4484

VL - 19

JO - Nanotechnology

JF - Nanotechnology

IS - 47

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Thickness-dependent phase transformation in nanoindented germanium thin films

Abstract

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