Authors’ contributions C-CW participated in the fabrication of Li

Authors’ contributions C-CW participated in the fabrication of Li doped NiO films, SEM, XRD and XPS analysis. C-FY participated in the Hall measurement and calculated the optical band gap of L-NiO. All authors read and approved the final manuscript.”
“Background Coupling system involving semiconductor nanocrystals (NCs) and metal nanoparticles (NPs) has been a subject of great SB202190 in vitro interest for the scientific community [1]. Due to the plasmon resonance in metal NPs, the interplay between NCs and NPs can modify the spectral features of NCs to improve emission efficiency as it involves the charge transfer across the semiconductor/metal interfaces [2]. Gold nanoparticles (AuNPs) are the subject of

increasing interests due to their essential properties and localized surface plasmon resonance in the visible spectrum wavelength [3]. The interplay effect in combining the gold and silicon is widely used in electronic devices in controlling their lifetime and resistivity [4, 5]. The AuNPs are mostly fabricated using a combination of chemical e-beam lithography and self-assembly techniques [6, 7] or by electron beam evaporation

[8]. However, the challenge is to control the size and position of the nanoparticles because these techniques tend to show a slightly broader size distribution. Mafuné et al. [9] have developed the laser ablation and laser-induced method to control the size of AuNPs without contamination. Nevertheless, this technique is very costly to implement. As an MEK phosphorylation alternative, electrodeposition technique can offer a solution to the problems as it is known for its simplicity and low processing cost [10]. Instead of using silicon as the substrate for the AuNP deposition, Fukami et al. [11] discovered the use of porous Si to control the shape and alignment of metal nanostructures. In this paper, we demonstrate that AuNPs supported on zinc oxide (ZnO) that was synthesized via the deposition-precipitation method can be deposited into porous silicon (PSi) using electrochemical deposition

(ECD) technique. The deposition-precipitation method has been proven to produce gold Ribonucleotide reductase particles of size less than 5 nm [12]. The growth parameters such as pore size distribution of PSi, metal solution concentration, and exposure time may have major influence on the AuNP growth. Methods Preparation of porous silicon using pulsed technique An n-type <100 > −oriented silicon wafer with a resistivity of 1 to 10 Ω cm was used to fabricate the PSi substrate. The substrate was cleaned in a wet chemical etching process, using RCA cleaning method. After cleaning, the samples were prepared using pulsed anodic etching method [13]. Output signal from the pulse current generator was used to feed the current at a constant peak of 10 mA/cm2 by adjusting the pause time (T off) at 4 ms with cycle time T all (14 ms). The electrolyte solution used was a mixture of hydrofluoric acid and ethanol, 1:4 by Selleck R788 volume.

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