Direct Observations of Twin Formation Dynamics in Binary Semiconductors

Overview

Journal ACS Nanosci Au

Publisher American Chemical Society

Specialty Biotechnology

Date 2023 Apr 27

PMID 37101516

Authors

Marcus Tornberg

Robin Sjokvist

Krishna Kumar

Christopher R Andersen

Carina B Maliakkal

Daniel Jacobsson

Kimberly A Dick

Affiliations

Soon will be listed here.

Abstract

With the increased demand for controlled deterministic growth of III-V semiconductors at the nanoscale, the impact and interest of understanding defect formation and crystal structure switching becomes increasingly important. Vapor-liquid-solid (VLS) growth of semiconductor nanocrystals is an important mechanism for controlling and studying the formation of individual crystal layers and stacking defects. Using studies, combining atomic resolution of transmission electron microscopy and controlled VLS crystal growth using metal organic chemical vapor deposition, we investigate the simplest achievable change in atomic layer stacking-single twinned layers formed in GaAs. Using Au-assisted GaAs nanowires of various diameters, we study the formation of individual layers with atomic resolution to reveal the growth difference in forming a twin defect. We determine that the formation of a twinned layer occurs significantly more slowly than that of a normal crystal layer. To understand this, we conduct thermodynamic modeling and determine that the propagation of a twin is limited by the energy cost of forming the twin interface. Finally, we determine that the slower propagation of twinned layers increases the probability of additional layers nucleating, such that multiple layers grow simultaneously. This observation challenges the current understanding that continuous uniform epitaxial growth, especially in the case of liquid-metal assisted nanowires, proceeds one single layer at a time and that its progression is limited by the nucleation rate.

Citing Articles

Observation of the Multilayer Growth Mode in Ternary InGaAs Nanowires.

Sjokvist R, Tornberg M, Marnauza M, Jacobsson D, Dick K ACS Nanosci Au. 2023; 2(6):539-548.

PMID: 37101854 PMC: 10125347. DOI: 10.1021/acsnanoscienceau.2c00028.

Epitaxial growth of crystal phase quantum dots in III-V semiconductor nanowires.

Lozano M, Gomez V Nanoscale Adv. 2023; 5(7):1890-1909.

PMID: 36998660 PMC: 10044505. DOI: 10.1039/d2na00956k.

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