We report catalyst-free direct synthesis of vertical graphene nanosheets
(VGNs) on SiO2/Si and quartz substrates using microwave electron cyclotron
resonance - plasma enhanced chemical vapor deposition. The evolution of VGNs is
studied systematically at different growth stages. Raman analysis as a function
of growth time reveals that two different disorder-induced competing mechanisms
contributing to the defect band intensity. The VGNs grown on SiO2/Si substrates
predominantly consists of both vacancy-like and hopping defects. On the other
hand, the VGNs grown on quartz substrates contain mainly boundary-like defects.
XPS studies also corroborate Raman analysis in terms of defect density and
vacancy-like defects for the VGNs grown on SiO2/Si substrates. Moreover, the
grown VGNs exhibit a high optical transmittance from 95 to 78 % at 550 nm and
the sheet resistance varies from 30 to 2.17 kohms/square depending on growth
time.Comment: 19 pages, 8 figures, 1 table; Accepted in Journal of Raman
Spectroscopy (2014
Applications of plasma-produced vertically oriented graphene nanosheets (VGNs) rely on their unique structure and morphology, which can be tuned by the process parameters to understand the growth mechanism. Here, we report on the effect of the key process parameters such as deposition temperature, discharge power and distance from plasma source to substrate on the catalyst-free growth of VGNs in microwave plasmas. A direct evidence for the initiation of vertical growth through nanoscale graphitic islands is obtained from the temperature-dependent growth rates where the activation energy is found to be as low as 0.57 eV. It is shown that the growth rate and the structural quality of the films could be enhanced by (a) increasing the substrate temperature, (b) decreasing the distance between the microwave plasma source and the substrate, and (c) increasing the discharge power. The correlation between the wetting characteristics, morphology and structural quality is established. It is also demonstrated that morphology, crystallinity, wettability and sheet resistance of the VGNs can be varied while maintaining the same sp3 content in the film. The effects of the substrate temperature and the electric field in vertical alignment of the graphene sheets are reported. These findings help to develop and optimize the process conditions to produce VGNs tailored for applications including sensing, field emission, catalysis and energy storage.
Growth of mono-dispersed AlGaN nanowires of ternary wurtzite phase is reported using chemical vapour deposition technique in the vapour-liquid-solid process. The role of distribution of Au catalyst nanoparticles on the size and the shape of AlGaN nanowires are discussed. These variations in the morphology of the nanowires are understood invoking Ostwald ripening of Au catalyst nanoparticles at high temperature followed by the effect of single and multi-prong growth mechanism. Energy-filtered transmission electron microscopy is used as an evidence for the presence of Al in the as-prepared samples. A significant blue shift of the band gap, in the absence of quantum confinement effect in the nanowires with diameter ~ 100 nm, is used as a supportive evidence for the AlGaN alloy formation. Polarized resonance Raman spectroscopy with strong electron-phonon coupling along with optical confinement due to the dielectric
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