Up to 40 % reduction of the GaAs band gap energy via strain engineering in core/shell nanowires

TL;DR

This paper demonstrates that strain engineering in core/shell GaAs nanowires can reduce the band gap energy by up to 40%, enabling new optoelectronic applications.

Contribution

It shows that large misfit strains in core/shell nanowires can significantly modify GaAs electronic properties without changing its composition.

Findings

Achieved up to 40% reduction in GaAs band gap energy.

Demonstrated strain regulation via shell composition and thickness.

Confirmed experimental results with theoretical calculations.

Abstract

The great possibilities for strain engineering in core/shell nanowires have been explored as an alternative route to tailor the properties of binary III-V semiconductors without changing their chemical composition. In particular, we demonstrate that the GaAs core in GaAs/In(x)Ga(1-x)As or GaAs/In(x)Al(1-x)As core/shell nanowires can sustain unusually large misfit strains that would have been impossible in conventional thin-film heterostructures. The built-in strain in the core can be regulated via the composition and the thickness of the shell. Thick enough shells become almost strain-free, whereas the thin core undergoes a predominantly-hydrostatic tensile strain, which causes the reduction of the GaAs band gap energy. For the highest strain of 7 % in this work (obtained for x=0.54), a remarkable reduction of the band gap by 40 % was achieved in agreement with theoretical calculations. Such strong modulation of its electronic properties renders GaAs suitable for near-infrared nano-photonics and presumably high electron mobility nano-transistors.