Fabrication of N-Type Nanocrystalline Silicon Thin-Film by Magnetron Sputtering and Antimony Induced Crystallization

Shekoofa, Omid; Wang, Jian; Li, Dejie

doi:10.47852/bonviewaaes32021040

Cited by 9 publications

(1 citation statement)

References 29 publications

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“…Recent research focuses on addressing these limitations through improved synthesis methods, characterization techniques, and surface modifications. Notably, functionalized MXenes with layer-dependent band gaps show enhanced photocatalytic performance [25]. Further research is needed to find the potential of MXene in photocatalysis and overcome its limitations to enable its widespread application in membrane materials.…”

Section: Introductionmentioning

confidence: 99%

Enhancing Oil–Water Separation Efficiency with WO3/MXene Composite Membrane

Amari,

Osman,

Boujelbene

et al. 2024

Water

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In this study, a novel method for the high-performance treatment of oily wastewater was introduced using a tungsten (VI) oxide (WO3)/MXene composite membrane based on poly (arylene ether sulfone) (PAES). Composite membranes were fabricated with superhydrophilic (SH) and superoleophobic (SO) characteristics, which allow for the high-performance treatment of oily wastewater. The fabricated composite membrane can also photodegrade organic types of pollutants with just a short period of UV, enabling self-cleaning and anti-fouling properties. Moreover, the comprehensive characterization of the composite membrane through FTIR, SEM, and XRD analyses yielded valuable insights. The FTIR analysis revealed the characteristic peaks of WO3, MXene, PAES, and the synthesized composite membrane, providing essential information on the chemical composition and properties of the materials. The XRD results demonstrated the crystal structures of WO3, MXene, PAES, and the synthesized composite membrane, further enhancing our understanding of the composite membrane. Additionally, the SEM images illustrated the surface and cross-section of the fabricated membranes, highlighting the differences in pore size and porosity between the PAES membrane and the WO3–MXene composite membrane, which directly impact permeate flux. The study showed that the composite membrane had a remarkable recovery time of only 0.25 h, and the efficiency of the separation process and water flux recovered to 99.98% and 6.4 L/m2.h, respectively. The joint influence of WO3 and MXene on composite membranes degraded contaminants into non-polluting substances after sunlight irradiation. This process effectively solves the treatment performance and decrease in permeate flux caused by contamination. The technology is membrane-based filtration, which is a simple and advanced method for treating polluted water. This innovative work offers promising solutions to address water pollution challenges and holds potential for practical applications from a self-cleaning and anti-fouling point of view.

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Section: Introductionmentioning

confidence: 99%

Enhancing Oil–Water Separation Efficiency with WO3/MXene Composite Membrane

Amari,

Osman,

Boujelbene

et al. 2024

Water

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Plant-mediated green route to the synthesis of zinc oxide nanoparticles: in vitro antibacterial potential

Takcı,

Ozdenefe,

Huner

et al. 2024

J Aust Ceram Soc

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The plant-mediated, sustainable, facile, eco-friendly, and simple green approaches for the fabrication of metal oxide nanoparticles (NPs) have recently attracted the ever-increasing attention of the scientific community. To date, there has not been any research on green synthesis of ZnO-NPs by Piper guineense (Uziza) seeds widely used as a therapeutic agent is the novelty of the current study. The bioaugmented ZnO-NPs have been manufactured by Uziza seed extract using zinc acetate dihydrate as the precursor and sodium hydroxide with calcination. The hexagonal/spherical crystalline structure at high purely with a mean size of 7.39 nm was confirmed via XRD and SEM analyses of ZnO-NPs. A strong absorption peak at about 350 nm, specific for ZnO-NPs, was observed by a UV-visible spectrometer. The optical bandgap of ZnO-NPs was estimated as about 3.58 eV by the Kubelka-Munk formula. FTIR findings indicated the presence of biofunctional groups responsible for the bioreduction of bulk zinc acetate to ZnO-NPs. The growth rates of E. coli (ATCC 25,922) significantly decreased with ZnO-NPs exhibited compared to the controls. This is making ZnO-NPs promising effective candidates for medical sectors and environmental applications. This current study is hoped to supply a better understanding of the phytosynthesis of ZnO-NPs and promote the advance of green approaches based on plants.

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