Teppo Huhtio scite author profile

We report for the first time the growth of GaAs nanowires directly on low-cost glass substrates using atmospheric pressure metal organic vapor phase epitaxy via a vapor-liquid-solid mechanism with gold as catalyst. Substrates used in this work were of float glass type typically seen in household window glasses. Growth of GaAs nanowires on glass were investigated for growth temperatures between 410 and 580 °C. Perfectly cylindrical nontapered nanowires with a growth rate of ~33 nm/s were observed at growth temperatures of 450 and 470 °C, whereas highly tapered pillar-like wires were observed at 580 °C. Nanowires grew horizontally on the glass surface at 410 °C with a tendency to grow in vertically from the substrate as the growth temperature was increased. X-ray diffraction and transmission electron microscopy revealed that the nanowires have a perfect zinc blende structure with no planar structural defects or stacking faults. Strong photoluminescence emission was observed both at low temperature and room temperature indicating a high optical quality of GaAs nanowires. Growth comparison on impurity free fused silica substrate suggests unintentional doping of the nanowires from the glass substrate.

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Second-Harmonic Generation Imaging of Semiconductor Nanowires with Focused Vector Beams

Bautista

Mäkitalo

Chen

et al. 2015

Nano Lett.

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We use second-harmonic generation (SHG) with focused vector beams to investigate individual vertically aligned GaAs nanowires. Our results provide direct evidence that SHG from oriented nanowires is mainly driven by the longitudinal field along the nanowire growth axis. Consequently, focused radial polarization provides a superior tool to characterize such nanowires compared to linear polarization, also allowing this possibility in the native growth environment. We model our experiments by describing the SHG process for zinc-blende structure and dipolar bulk nonlinearity.

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Influence of plasma chemistry on impurity incorporation in AlN prepared by plasma enhanced atomic layer deposition

Perros¹,

Hakola²,

Sajavaara³

et al. 2013

J. Phys. D: Appl. Phys.

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Strong surface passivation of GaAs nanowires with ultrathin InP and GaP capping layers

Haggrén

Jiang

Kakko

et al. 2014

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Teppo Huhtio

Properties of AlN grown by plasma enhanced atomic layer deposition

High Quality GaAs Nanowires Grown on Glass Substrates

Second-Harmonic Generation Imaging of Semiconductor Nanowires with Focused Vector Beams

Influence of plasma chemistry on impurity incorporation in AlN prepared by plasma enhanced atomic layer deposition

Strong surface passivation of GaAs nanowires with ultrathin InP and GaP capping layers

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