Accurate strain measurements in highly strained Ge microbridges

Accurate strain measurements in highly strained Ge microbridges

Ge under high strain is predicted to become a direct bandgap semiconductor. Very large deformations can be introduced using microbridge devices. However, at the microscale, strain values are commonly deduced from Raman spectroscopy using empirical linear models only established up to 1.2% for uniaxi...

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Veröffentlicht in:arXiv.org 2016-04
Hauptverfasser: Gassenq, A, Tardif, S, Guilloy, K, Dias, G Osvaldo, Pauc, N, Duchemin, I, Rouchon, D, J-M Hartmann, Widiez, J, Escalante, J, Y-M Niquet, Geiger, R, Zabel, T, Sigg, H, Faist, J, Chelnokov, A, Rieutord, F, Reboud, V, Calvo, V
Format: Artikel
Sprache:eng
Schlagworte:
Deformation
Physics - Materials Science
Raman spectroscopy
Tensile strain
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Zusammenfassung:Ge under high strain is predicted to become a direct bandgap semiconductor. Very large deformations can be introduced using microbridge devices. However, at the microscale, strain values are commonly deduced from Raman spectroscopy using empirical linear models only established up to 1.2% for uniaxial stress. In this work, we calibrate the Raman-strain relation at higher strain using synchrotron based microdiffraction. The Ge microbridges show unprecedented high tensile strain up to 4.9 % corresponding to an unexpected 9.9 cm-1 Raman shift. We demonstrate experimentally and theoretically that the Raman strain relation is not linear and we provide a more accurate expression.
ISSN:2331-8422
DOI:10.48550/arxiv.1604.04391