Joshua M. LaForge scite author profile

A new growth technique for indium tin oxide nanowhiskers with increased control over feature size and spacing is reported. The technique is based on a unique combination of self-catalysed vapour-liquid-solid (VLS) growth and glancing angle deposition (GLAD). This VLS-GLAD technique provides enhanced control over nanowhisker morphology as the effect of typical VLS growth parameters (e.g. flux rate, temperature) is amplified at large deposition angles characteristic of GLAD. Spatial modulation of the collimated growth flux controls trunk width, number and orientation of branches, and overall nanowhisker density. Here we report the influence of growth conditions (including deposition angle, flux rate, nominal pitch and substrate temperature) on nanowhisker morphology, with specific focus on the effect of large deposition angles. Sheet resistance and transmission of the films were measured to characterize their performance as transparent conductive oxides. Hybrid nanostructured films grown in this study include high surface area nanowhiskers protruding from a conductive film, ideal for transparent conductive electrode applications.

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Flux Engineering for Indium Tin Oxide Nanotree Crystal Alignment and Height-Dependent Branch Orientation

Beaudry

LaForge

Tucker

et al. 2012

Crystal Growth & Design

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rotation), (b) periodic, (c) chiral and (d) isotropic based on the azimuthal modulation configuration used during growth, shown in Figure 2. The initial azimuthal vapour flux angle ( 0 ) is oriented from the right to left in each image. The nominal thickness of all films is 1200 nm.Figure S2. Top-SEMs of unidirectional, periodic, chiral and isotropic films (from left to right). The top and bottom rows show structures grown at 0.2 nm s -1 and 2 nm s -1 , respectively.

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Conductivity control of as-grown branched indium tin oxide nanowire networks

LaForge¹,

Cocker²,

Beaudry³

et al. 2013

Nanotechnology

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Branched indium tin oxide (ITO) nanowire networks are promising candidates for transparent conductive oxide applications, such as optoelectronic electrodes, due to their high porosity. However, these branched networks also present new challenges in assessing conductivity. Conventional four-point probe techniques cannot separate the effect of porosity on the long-range conductivity from the intrinsic material conductivity. Here we compare the average nanoscale conductivity within the film measured by terahertz time-domain spectroscopy (THz-TDS) to the film conductivity measured by four-point probe in a branched ITO nanowire network. Both techniques report conductivity increases with deposition flux rate from 0.5 to 3.0 nm s(-1), achieving a maximum of ~ 10 (Ω cm)(-1). Modeling the THz-TDS conductivity data using the Drude-Smith model allows us to distinguish between conductivity increases resulting from morphological changes and those resulting from the intrinsic properties of the ITO. In particular, the intrinsic material conductivity within the nanowires can be extracted, and is found to reach a maximum of ~ 3000 (Ω cm)(-1), comparable to bulk ITO. To determine the mechanism responsible for increasing conductivity with flux rate, we characterize dopant concentration and morphological changes (i.e., to branching behavior, nanowire diameter and nucleation layers). We propose that changes in the electron density, primarily due to changes in O-vacancy concentration at different flux rates, are responsible for the observed conductivity increase. This understanding will assist balancing structural and conductivity requirements in applications of transparent conductive oxide networks.

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Glancing angle deposition of crystalline zinc oxide nanorods

2011

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Directed Branch Growth in Aligned Nanowire Arrays

et al. 2014

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Branch growth is directed along two, three, or four in-plane directions in vertically aligned nanowire arrays using vapor-liquid-solid glancing angle deposition (VLS-GLAD) flux engineering. In this work, a dynamically controlled collimated vapor flux guides branch placement during the self-catalyzed epitaxial growth of branched indium tin oxide nanowire arrays. The flux is positioned to grow branches on select nanowire facets, enabling fabrication of aligned nanotree arrays with L-, T-, or X-branching. In addition, a flux motion algorithm is designed to selectively elongate branches along one in-plane axis. Nanotrees are found to be aligned across large areas by X-ray diffraction pole figure analysis and through branch length and orientation measurements collected over 140 μm(2) from scanning electron microscopy images for each array. The pathway to guided assembly of nanowire architectures with controlled interconnectivity in three-dimensions using VLS-GLAD is discussed.

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Joshua M. LaForge

Indium tin oxide nanowhisker morphology control by vapour–liquid–solid glancing angle deposition

Flux Engineering for Indium Tin Oxide Nanotree Crystal Alignment and Height-Dependent Branch Orientation

Conductivity control of as-grown branched indium tin oxide nanowire networks

Glancing angle deposition of crystalline zinc oxide nanorods

Directed Branch Growth in Aligned Nanowire Arrays

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