Your search keyword '"Mtshali, C."' showing total 4 results

1. Zn and W Co-doped VO2-Based Thin Films Prepared by DC Magnetron Sputtering: Improved Luminous Transmittance and Reduced Transition Temperature.

Author

Haji, H. F., Numan, N., Madiba, I. G., Mabakachaba, B., Mtshali, C., Khumalo, Z., Kotsedi, L., Mlyuka, N., Samiji, M., and Maaza, M.

Subjects

TRANSITION temperature, THIN films, DC sputtering, MAGNETRON sputtering, PHASE transitions, DOPING agents (Chemistry)

Abstract

Un-doped VO2, tungsten (W)-doped VO2, and W/Zn co-doped VO2 thin films were successfully prepared by two DC magnetron sources and co-sputtered at a substrate temperature of 425°C onto soda lime glass substrates. The aim was to find whether co-doping of VO2 films with W and Zn could decrease the transition temperature and increase both luminous transmittance and solar transmittance modulation (ΔTsol) of VO2 -based thin films. The thin films were characterized by x-ray diffraction, atomic force microscopy, Rutherford backscattering spectroscopy, the two-point probe technique, Hall effect measurement system, and a PerkinElmer Lambda 1050+ UV/VIS/NIR) spectrometer. This work revealed that a controlled amount of Zn in the W-doped VO2 films showed solar transmittance modulation of 4%. It further improves the luminous transmittance to ~ 46%, lowering the phase transition temperature to below 27°C, compared to un-doped VO2 and W-doped VO2 thin films at 64.8°C and 44°C, respectively. These results show that the combined effect of W and Zn doping on VO2 films has the potential to make the films useful for smart window applications. [ABSTRACT FROM AUTHOR]

Published

2023

2. Solid state dewetting of a metal –semiconductor bi-layers deposited onto c-Si substrate.

Author

Halindintwali, S., Masenya, M., Madhuku, M., Mtshali, C., Cummings, F., and Oliphant, C.

Subjects

SEMICONDUCTOR thin films, MIXING height (Atmospheric chemistry), MULTILAYERS, NANOPARTICLE size, SEMICONDUCTORS

Abstract

A bi-layers stack consisting of a semiconductor thin film of a varied thickness and a very thin Pd layer (SiC/Pd/c-Si).was deposited onto c-Si by e-beam evaporation at room temperature. The multi-layers structure was subjected to a thermal annealing process at near eutectic temperature of the Si – Pd phase. It is noticed, through top view SEM and cross-section STEM analyses, that the sandwiched Pd metal layer dewets from the interface with the c-Si substrate in well dispersed nanoparticles and it diffuses inward onto the top few monolayers of the substrate; at times it permeates shallowly through the SiC semiconductor top layer. The size distribution of the nanoparticles was found to be closely linked to the thickness of the top semiconductor layer. On the other hand, the top SiC layer was found to form islands protruding above the surface, when the film was very thin. When thicker, the semiconductor SiC layer retained its integrity and remained unaffected. An optical model of the resulting metal-dielectric mixed layer is proposed. [ABSTRACT FROM AUTHOR]

Published

2023

3. Corrosion Resistance of Ni-Based WC/Co Coatings Deposited by Spray and Fuse Process Varying the Oxygen Flow.

Author

Jiménez, H., Olaya, J., Alfonso, J., Mtshali, C., and Pineda-Vargas, C.

Subjects

METAL spraying, PLASMA spraying, METAL coating, CORROSION & anti-corrosives, CAST-iron, STANDARDS

Abstract

In this work, the effect of oxygen flow variation in the corrosion behavior of Ni-based WC/Co coatings deposited by spray and fuse process was investigated. The coatings were deposited on gray cast iron substrates using a Superjet Eutalloy thermal spraying gun. The morphology of the coatings was analyzed using scanning electron microscopy. The crystallographic phases were registered by x-ray diffraction (XRD), the diffraction patterns show the crystalline phases of the powder components with principal reflections for Ni and WC, the increase in flame temperature, due to the oxygen flow variation, generated amorphization in the nickel and an important crystallization of the planes (111) and (222) of WC as well as the decarburization of WC in WC and W metallic. The corrosion behavior was investigated at room temperature in a 3.5% w/w aqueous solution of NaCl via potentiodynamic polarization. Electrochemical corrosion test showed that the coatings deposited under neutral flame conditions with an oxygen flow of 12.88 SCFH evidenced higher corrosion resistance. The chemical composition of the coatings and corrosion areas were analyzed by particle-induced x-ray emission, this technique permitting the corroboration of the decarburization process of WC determined by XRD and the formation of Cl structures. [ABSTRACT FROM AUTHOR]

Published

2017

4. Thermal conductivity enhancement in gold decorated graphene nanosheets in ethylene glycol based nanofluid.

Author

Mbambo, M. C., Madito, M. J., Khamliche, T., Mtshali, C. B., Khumalo, Z. M., Madiba, I. G., Mothudi, B. M., and Maaza, M.

Subjects

GOLD nanoparticle synthesis, THERMAL conductivity measurement, GRAPHENE synthesis, NANOFLUIDS, ETHYLENE glycol, NEODYMIUM lasers

Abstract

We report on the synthesis and thermal conductivity of gold nanoparticles (AuNPs) decorated graphene nanosheets (GNs) based nanofluids. The GNs-AuNPs nanocomposites were synthesised using a nanosecond pulsed Nd:YAG laser (wavelength = 1,064 nm) to ablate graphite target followed by Au in ethylene glycol (EG) base fluid to obtain GNs-AuNPs/EG hybrid nanofluid. The characterization of the as-synthesised GNs-AuNPs/EG hybrid nanofluid confirmed a sheet-like structure of GNs decorated with crystalline AuNPs with an average particle diameter of 6.3 nm. Moreover, the AuNPs appear smaller in the presence of GNs which shows the advantage of ablating AuNPs in GNs/EG. The thermal conductivity analysis in the temperature range 25–45 °C showed that GNs-AuNPs/EG hybrid nanofluid exhibits an enhanced thermal conductivity of 0.41 W/mK compared to GNs/EG (0.35 W/mK) and AuNPs/EG (0.39 W/mK) nanofluids, and EG base fluid (0.33 W/mK). GNs-AuNPs/EG hybrid nanofluid displays superior enhancement in thermal conductivity of up to 26% and this is due to the synergistic effect between AuNPs and graphene sheets which have inherent high thermal conductivities. GNs-AgNPs/EG hybrid nanofluid has the potential to impact on enhanced heat transfer technological applications. Also, this work presents a green synthesis method to produce graphene-metal nanocomposites for various applications. [ABSTRACT FROM AUTHOR]

Published

2020