AI Article Synopsis
- Core-shell Ge/Ge1-xSnx nanowires are explored for their potential in optoelectronics due to their compatibility with silicon and the ability to achieve a direct band-gap.* -
- The study uses a phase field method to model the growth of these nanowires, analyzing factors like chemical potential and tin concentration that impact the shell formation.* -
- Three distinct growth stages were identified: accelerated growth, constant growth, and reduced growth, which help clarify the mechanisms of core-shell nanowire formation and guide future synthesis methods.*
Article Abstract
Core-shell Ge/Ge1-xSnx nanowires are considered promising silicon-compatible nanomaterials with the potential to achieve a direct band-gap for optoelectronic applications. In this study, we systematically investigated the formation of this heterostructure in the radial direction by the phase field method coupled with elasticity. Our model simulated the shell growth of the wire, capturing the evolution of both the sidewall morphology and the strain distribution. We predicted the minimum chemical potential driving forces required for initiating the Ge1-xSnx shell growth at given tin concentrations. In addition, we studied the dependences of the shell growth rate on the chemical potential, the tin concentration, the sidewall interface kinetics and the mass transport rate respectively. From these analyses, we identified three sequential stages of the growth: the Stage 1 growth at an accelerated rate, the Stage 2 growth at a constant rate, and finally the Stage 3 growth at a reduced rate scaling with . This research improves our current understanding on the growth mechanisms of heterogeneous core-shell nanowires, and provides useful guidelines for optimizing nanowire synthesis pathways.
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| http://dx.doi.org/10.1039/c9nr07587a | DOI Listing |
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