Photoelectric properties of metal-semiconductor-metal photodetector based on porous silicon

Metal-semiconductor-metal (MSM) photodetector was fabricated on a Porous silicon (PS) layer that was prepared using photo electrochemical etching (PEC). The surface morphology of the PS was carried out by field emission scanning electron microscopy. The I-V characteristics under dark and illuminated conditions and the responsivity of Pt-PS-Si heterostructures were investigated. The device exhibited that photogeneration in heterojunction happens in each of the regions of the porous Si film and Si substrate. The MSM photodetector exhibited sensitivity of 3.22×102 as well as inner gain of 4.22 when exposed to tungsten lamp at 5 V. The photodetector also shows good repeatability when illuminated with 460 nm (7 W/cm2) chopped light and the saturation current increased as the voltage increase

The correlation of blue shift of photoluminescence and morphology of silicon nanoporous

Porous silicon with diameters ranging from 6.41 to 7.12 nm were synthesized via electrochemical etching by varied anodization current density in ethanoic solutions containing aqueous hydrofluoric acid up to 65mA/cm2.The luminescence properties of the nanoporous at room temperature were analyzed via photoluminescence spectroscopy. Photoluminescence PL spectra exhibit a broad emission band in the range of 360-700 nm photon energy. The PL spectrum has a blue shift in varied anodization current density; the blue shift incremented as the existing of anodization although the intensity decreased. The current blue shift is owning to alteration of silicon nanocrystal structure at the superficies. The superficial morphology of the PS layers consists of unified and orderly distribution of nanocrystalline Si structures, have high porosity around (93.75%) and high thickness 39.52 µm

Impact of ablation time on Cu oxide nanoparticle green synthesis via pulsed laser ablation in liquid media

Large-scale commercial production of nanoparticles via efficient, economical, and environmentally friendly methods is a challenging endeavour. The laser ablation method being a green and potential route of nanoparticles synthesis can be exploited to achieve this end. In this work, we report the ablation of a copper target submerged in distilled water by pulsed Nd:YAG laser. The influence of ablation time on the structure and optical properties of grown copper oxide nanoparticles are studied. Such nanoparticle composition and structure is determined by X-ray diffraction (XRD), Fourier transform infrared, and Raman analyses. Results from transmission electron microscopy images established that synthesised nanoparticles are a spherical shape with average sizes of 24–37 nm. Fluorescence spectra revealed the enhancement of nanoparticle concentration and reduction in the sizes with increasing ablation time, where the optimum ablation time is demonstrated to be 60 min. Photoluminescence spectra exhibited a prominent visible peak (green), which blueshifted from 542 to 537 nm, confirming the shrinkage of copper oxide particle size at higher ablation time. The XRD pattern showed that the prepared nanoparticles possess a single phase of monocline cupric oxide nanostructure