Influence of hole shape/size on the growth of site-selective quantum dots

Mayer, Christian; Helfrich, Mathieu; Schaadt, D. M.

doi:10.1186/1556-276x-8-504

Cited by 7 publications

(4 citation statements)

References 39 publications

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“…Table 1 shows a comparison between the nanohole depths used for the site-controlled growth of InAs QDs on GaAs. A range of techniques are In this study, we observed a low standard deviation (SD) in nanohole radius and depth which is an encouraging result for reducing inhomogeneity in site-controlled QD size, emission wavelength and occupancy [27,28]. The SD in radius was between 15 and 3 nm, with no trend seen when increasing voltage or humidity.…”

Section: Resultssupporting

confidence: 51%

Nanoscale wafer patterning using SPM induced local anodic oxidation in InP substrates

Ovenden

Farrer

Skolnick

et al. 2021

Semicond. Sci. Technol.

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Scanning probe microscopy assisted local anodic oxidation offers advantages over other semiconductor fabrication techniques as it is a low contamination method. We demonstrate the fabrication of deep and highly reproducible nanohole arrays on InP using local anodic oxidation. Nanohole and nano-oxide mound radius and depth are controlled independently by altering atomic force microscope tip bias and humidity, with a maximum nanohole depth of 15.6 ± 1.2 nm being achieved. Additionally, the effect of tip write speed on oxide line formation is compared for n-type, p-type and semi-insulating substrates, which shows that n-type InP oxidises at a slower rate that semi-insulated or p-type InP. Finally, we calculate the activation energy for LAO of semi-insulating InP to be 0.4 eV, suggesting the oxidation mechanism is similar to that which occurs during plasma oxidation.

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Section: Resultssupporting

confidence: 51%

Nanoscale wafer patterning using SPM induced local anodic oxidation in InP substrates

Ovenden

Farrer

Skolnick

et al. 2021

Semicond. Sci. Technol.

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“…As the actual shape of pits does influence the energy of the system and, more in general, island nucleation [ 26 , 27 ], it is crucial to control their morphology. This is not trivial: after all, pits are just holes drilled into the substrate.…”

Section: Introductionmentioning

confidence: 99%

Morphological Evolution of Pit-Patterned Si(001) Substrates Driven by Surface-Energy Reduction

et al. 2017

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Lateral ordering of heteroepitaxial islands can be conveniently achieved by suitable pit-patterning of the substrate prior to deposition. Controlling shape, orientation, and size of the pits is not trivial as, being metastable, they can significantly evolve during deposition/annealing. In this paper, we exploit a continuum model to explore the typical metastable pit morphologies that can be expected on Si(001), depending on the initial depth/shape. Evolution is predicted using a surface-diffusion model, formulated in a phase-field framework, and tackling surface-energy anisotropy. Results are shown to nicely reproduce typical metastable shapes reported in the literature. Moreover, long time scale evolutions of pit profiles with different depths are found to follow a similar kinetic pathway. The model is also exploited to treat the case of heteroepitaxial growth involving two materials characterized by different facets in their equilibrium Wulff’s shape. This can lead to significant changes in morphologies, such as a rotation of the pit during deposition as evidenced in Ge/Si experiments.

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“…In molecular beam epitaxy (MBE) processes, this can be achieved by defining the nucleation sites for impinging atoms using patterning the surface. Patterning is usually accomplished by lithographic techniques, such e-beam lithography [7][8][9][10][11], nanoimprint lithography [12], interference lithography, photolithography [13], or atomic force microscopy (AFM) lithography [14].…”

Section: Introductionmentioning

confidence: 99%

The Role of Groove Periodicity in the Formation of Site-Controlled Quantum Dot Chains

Schramm¹,

Hakkarainen²,

Tommila³

et al. 2016

Nano Online

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Structural and optical properties of InAs quantum dot (QD) chains formed in etched GaAs grooves having different periods from 200 to 2000 nm in [010] orientation are reported. The site-controlled QDs were fabricated by molecular beam epitaxy on soft UV-nanoimprint lithography-patterned GaAs(001) surfaces. Increasing the groove periods decreases the overall QD density but increases the QD size and the linear density along the groove direction. The effect of the increased QD size with larger periods is reflected in ensemble photoluminescence measurements as redshift of the QD emission. Furthermore, we demonstrate the photoluminescence emission from single QD chains.

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Influence of hole shape/size on the growth of site-selective quantum dots

Cited by 7 publications

References 39 publications

Nanoscale wafer patterning using SPM induced local anodic oxidation in InP substrates

Nanoscale wafer patterning using SPM induced local anodic oxidation in InP substrates

Morphological Evolution of Pit-Patterned Si(001) Substrates Driven by Surface-Energy Reduction

The Role of Groove Periodicity in the Formation of Site-Controlled Quantum Dot Chains

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