posted on 2020-04-23, 17:08authored bySijia Ran, Tom S. Glen, Bei Li, Dongliang Shi, In-Suk Choi, Eugene A. Fitzgerald, Steven T. Boles
Speculations
regarding electronic and photonic properties of strained
germanium (Ge) have perpetually put it into contention for next-generation
devices since the start of the information age. Here, the electromechanical
coupling of <111> Ge nanowires (NWs) is reported from unstrained
conditions to the ultimate tensile strength. Under tensile strain,
the conductivity of the NW is enhanced exponentially, reaching an
enhancement factor of ∼130 at ∼3.5% of strain. Under
strains larger than ∼2.5%, the electrical properties of Ge
also exhibit a dependence on the electric field. The conductivity
can be further enhanced by ∼2.2× with a high bias condition
at ∼3.5% of strain. Cyclic loading tests confirm that the observed
electromechanical responses are repeatable, reversible, and related
to the changing electronic band structure. These tests reveal the
excellent prospects for utilizing strained Ge NWs in photodetector
or piezoelectronic transistor applications, but significant challenges
remain to realize strict direct band gap devices.