Kevin A. Grossklaus scite author profile

Driven by tensile strain, GaAs quantum dots (QDs) self-assemble on In0.52Al0.48As(111)A surfaces lattice-matched to InP substrates. In this study, we show that the tensile-strained self-assembly process for these GaAs(111)A QDs unexpectedly deviates from the well-known Stranski-Krastanov (SK) growth mode. Traditionally, QDs formed via the SK growth mode form on top of a flat wetting layer (WL) whose thickness is fixed. The inability to tune WL thickness has inhibited researchers’ attempts to fully control QD-WL interactions in these hybrid 0D-2D quantum systems. In contrast, using microscopy, spectroscopy, and computational modeling, we demonstrate that for GaAs(111)A QDs, we can continually increase WL thickness with increasing GaAs deposition, even after the tensile-strained QDs (TSQDs) have begun to form. This anomalous SK behavior enables simultaneous tuning of both TSQD size and WL thickness. No such departure from the canonical SK growth regime has been reported previously. As such, we can now modify QD-WL interactions, with future benefits that include more precise control of TSQD band structure for infrared optoelectronics and quantum optics applications.

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Red-Emitting (<inline-formula> <tex-math notation="TeX">\(\lambda = 610\) </tex-math></inline-formula> nm) In<sub>0.51</sub>Ga<sub>0.49</sub>N/GaN Disk-in-Nanowire Light Emitting Diodes on Silicon

Jahangir

Schimpke

Straßburg

et al. 2014

IEEE J. Quantum Electron.

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Mechanisms of nanodot formation under focused ion beam irradiation in compound semiconductors

Grossklaus

Millunchick

2011

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We have examined the responses of GaAs, InP, InAs, and AlAs to 30 keV focused ion beam ͑FIB͒ irradiation and applied a unified model that consistently explains the observed effects. Nanodots were observed to form on GaAs, InP, and InAs under irradiation at normal incidence, while nanodots are not observed on AlAs. The FIB response and nanodot formation behavior of each material is discussed with regard to a few basic material properties and a model for nanodot creation and growth by the action of preferential sputtering and Ostwald ripening. The model predicts the development of a stable average nanodot size with increasing ion dose, with the average nanodot size depending on the excess group III adatom yield, adatom surface diffusion rate, and surface tension. These predictions qualitatively agree with the experimentally observed trends for GaAs and InP. They also agree for the initial nanodot formation on InAs, but this material system exhibits a sudden transition in the nanodot size distribution. The model predicts that nanodots will have difficulty forming and growing on AlAs, which is also in agreement with our experimental results.

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Self-assembly of tensile-strained Ge quantum dots on InAlAs(111)A

Sautter

Schuck

Garrett

et al. 2020

Journal of Crystal Growth

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