6533b836fe1ef96bd12a0af7

RESEARCH PRODUCT

Investigating the mechanical properties of GeSn nanowires.

Donats ErtsJessica DohertyJelena KosmacaGunta KunakovaMikk AntsovEmerson CoyRaimonds MeijaJustin D. HolmesJustin D. HolmesRaitis SondorsSubhajit BiswasSubhajit BiswasIgor Iatsunskyi

subject

Materials scienceAlloyNanowirechemistry.chemical_elementGermanium02 engineering and technologyBendingengineering.material010402 general chemistry01 natural sciencesGeneral Materials ScienceMechanical resonanceNanoscopic scaleGermanium tin alloybusiness.industryMechanical behaviour021001 nanoscience & nanotechnology0104 chemical sciencesNanowirechemistryengineeringOptoelectronicsSize dependence0210 nano-technologyTinbusinessLayer (electronics)

description

Germanium tin (GeSn) has been proposed as a promising material for electronic and optical applications due to the formation of a direct band-gap at a Sn content >7 at%. Furthermore, the ability to manipulate the properties of GeSn at the nanoscale will further permit the realisation of advanced mechanical devices. Here we report for the first time the mechanical properties of GeSn nanowires (7.1-9.7 at% Sn) and assess their suitability as nanoelectromechanical (NEM) switches. Electron microscopy analysis showed the nanowires to be single crystalline, with surfaces covered by a thin native amorphous oxide layer. Mechanical resonance and bending tests at different boundary conditions were used to obtain size-dependent Young's moduli and to relate the mechanical characteristics of the alloy nanowires to geometry and Sn incorporation. The mechanical properties of the GeSn nanowires make them highly promising for applications in next generation NEM devices.

yearjournalcountryeditionlanguage
2019-07-11Nanoscale
10.1039/c9nr02740hhttps://pubmed.ncbi.nlm.nih.gov/31290891