Nano/Micro-Structured ZnO Rods Synthesized by Thermal Chemical Vapor Deposition with Perpendicular Configuration

Under a one-step process, catalyst-free growth of one-dimensional (1D) ZnO hierarchical nanostructures was performed on ZnO-seeded Si substrate by thermal chemical vapor deposition with a perpendicular setup. The morphological and crystallographic properties of the nano/micro-structured ZnO rods were investigated with varying growth temperature and growth time. X-ray diffraction patterns of 1D ZnO double-structured rods showed the hexagonal wurtzite structure. The morphology and crystal structure of the ZnO double-structured rods were sensitive to the growth temperature and growth time. From Raman scattering and photoluminescence spectra, the orientation and size effects of the ZnO double-structured rods were discussed in relation to growth temperatures and growth times.

Process dependent strain behaviour, fractal analysis, and bonding network of nc-Si(SiC) thin films

Nanocrystalline silicon embedded silicon carbide, nc-Si(SiC) thin films were deposited on p-type silicon substrates by using a thermal chemical vapor deposition (CVD) with different process temperatures varied from 700-1000oC. The SEM images reveal the Si particles are embedded with SiC thin films. The estimated lattice-strainof nc-Si(SiC) thin films from Williamson-Hall and Scherer formula was varied from 0.00227 to 0.00469 and 0.000855 to 0.00574 respectively. The Raman signature at the 1346.19 cm− 1, 1491.78 cm− 1 and 1570.94 cm− 1 bonding correspond to D, G-Si and G peaks respectively. The estimated band gap from Tauc’s plot of nc-Si(SiC) thin films are 3.17 to 2.87 eV respectively with increasing of process temperature. The observed crystalline size of nc-Si in nc-Si(SiC) is from 21 nm to 27 nm from 700 to 1000 oC respectively. The possible bonding network of core-orbital of Si(2p), C(1s), and O(1s) in the C: ZnO thin films have been discussed by deconvolution with the Origin 2018.

Graphitic Nanocup Architectures for Advanced Nanotechnology Applications

The synthesis of controllable hollow graphitic architectures can engender revolutionary changes in nanotechnology. Here, we present the synthesis, processing, and possible applications of low aspect ratio hollow graphitic nanoscale architectures that can be precisely engineered into morphologies of (1) continuous carbon nanocups, (2) branched carbon nanocups, and (3) carbon nanotubes–carbon nanocups hybrid films. These complex graphitic nanocup-architectures could be fabricated by using a highly designed short anodized alumina oxide nanochannels, followed by a thermal chemical vapor deposition of carbon. The highly porous film of nanocups is mechanically flexible, highly conductive, and optically transparent, making the film attractive for various applications such as multifunctional and high-performance electrodes for energy storage devices, nanoscale containers for nanogram quantities of materials, and nanometrology.