Metal Oxides‐Based Nano/Microstructures for Photodegradation of Microplastics

Kumar, Rajesh

doi:10.1002/adsu.202300033

Cited by 11 publications

(1 citation statement)

References 179 publications

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“…Table 3 illustrates the zeta potential for ZnO, Fe10%:ZnO, and Fe20%:ZnO is 0.2 mV, 0.4 mV, and 0.6 mV, respectively, and the last one is 0.9 mV for Fe30%:ZnO. This rise is explained by the iron atoms functioning as electron donors, which raises the electron density and encourages electron ow across the Fe-ZnO interface [33].…”

Section: Zeta Potential Analysismentioning

confidence: 96%

Enhanced Biocompatibility and Multifunctional Properties of Iron-Doped Zinc Oxide Nanoparticles for Applications

Foyshal,

Kabir,

Islam

et al. 2024

BioNanoSci.

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Nanoparticles' enhanced biocompatibility and multifunctional properties for medical applications, including advanced drug delivery systems, nanotheranostics, in vivo imaging, and electronic device fabrication, have attracted considerable interest. ZnO and iron-doped ZnO (Fe:ZnO) nanoparticles (NPs) were synthesized using the wet-chemical process. X-ray diffraction (XRD) analysis illustrates that the crystallite dimension of these nanoparticles decreased as iron (Fe) concentration increased up to 20 wt%. The crystallite dimension reduced from 89.63 nm to 70.47 nm as the iron content grew, and then it continued to increase as the iron proportion increased. The particle size of these nanoparticles was evaluated by scanning electron microscopy (SEM) and determined to be between 80 nm and 110 nm. The functional group of active Fe:ZnO samples shows the FT-IR peaks at approximately 399 cm − 1 , 750 cm − 1 , between 3500 cm − 1 and 3600 cm − 1, and 1420 cm − 1 ascribed to the Zn-O, -CH 2 -NH 2 , -OH, and -CO vibrations, respectively. Whereas the peaks at 2860 cm − 1 and 2925 cm − 1 were attributed to the -CH 3 and -CH 2 stretching vibrations, respectively. Dynamic light scattering (DLS) was also used to determine the hydrodynamic diameter of ZnO and Fe:ZnO NPs. Zeta potential values for ZnO, Fe10%:ZnO, Fe20%:ZnO, and Fe30%:ZnO were 0.2 mV, 0.4 mV, 0.6 mV, and 0.9 mV, respectively. All samples exhibited strong absorption peaks at 350 nm in the UV region. The band gap energy of Fe:ZnO decreased as the Fe concentration increased. The band gap energies calculated using UV-Vis data were at about 3.06 eV, 2.92 eV, 2.82 eV, and 2.78 eV for ZnO, Fe10%:ZnO, Fe20%:ZnO, and Fe30%:ZnO, respectively. The outcomes of the research may have potential applications in semiconductor device fabrication, including spintronics and nanomedicine.

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Section: Zeta Potential Analysismentioning

confidence: 96%

Enhanced Biocompatibility and Multifunctional Properties of Iron-Doped Zinc Oxide Nanoparticles for Applications

Foyshal,

Kabir,

Islam

et al. 2024

BioNanoSci.

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Magnetic Manganese‐Based Micromotors MnFe₂O₄@Fe₃O₄/graphite and Mn₂O₃@Fe₂O₃@Fe₃O₄/graphite for Organic Pollutant Degradation

Kichatov,

Korshunov,

Sudakov

et al. 2023

Advanced Sustainable Systems

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Wastewater pollution with organic compounds poses a serious threat to human health. One of the possible methods for solving these problems can be the use of micro/nanomotors. Among them, manganese‐based micro/nanomotors have a number of important advantages related to high catalytic activity, powerful motion, and low cost. Due to their mobility, micro/nanomotors promote an increase in the intensity of mass transfer in the reacting system. When introducing ferromagnetic elements into manganese‐based micro/nanomotors, it is possible not only to increase their motion speed, but also to make their motion more controllable. Herein, for the first time it demonstrates a synthesis method for MnFe2O4@Fe3O4/graphite and Mn2O3@Fe2O3@Fe3O4/graphite magnetic catalytic micromotors, which have remarkable photocatalytic properties. Micromotors are clusters of nanoparticles whose motion in a hydrogen peroxide solution in a non‐uniform magnetic field is caused by the action of magnetic force and self‐diffusiophoresis. Nanoparticles are synthesized by the plasma‐arc method with subsequent annealing in the air. When changing the annealing temperature, the catalytic and magnetic properties of nanoparticles can vary within a wide range of values. Micromotors MnFe2O4@Fe3O4/graphite have the most optimal catalytic and magnetic properties. The results of the research show that these micromotors are effective catalysts in the decomposition of methylene blue.

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Advanced and Smart Technology for Sustainable Management of Microfiber Waste

Rao

2024

Renewable Energy Generation and Value Addition From Environmental Microfiber Pollution Through Advanced Greener Solution

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Metal Oxides‐Based Nano/Microstructures for Photodegradation of Microplastics

Cited by 11 publications

References 179 publications

Enhanced Biocompatibility and Multifunctional Properties of Iron-Doped Zinc Oxide Nanoparticles for Applications

Enhanced Biocompatibility and Multifunctional Properties of Iron-Doped Zinc Oxide Nanoparticles for Applications

Magnetic Manganese‐Based Micromotors MnFe₂O₄@Fe₃O₄/graphite and Mn₂O₃@Fe₂O₃@Fe₃O₄/graphite for Organic Pollutant Degradation

Advanced and Smart Technology for Sustainable Management of Microfiber Waste

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Metal Oxides‐Based Nano/Microstructures for Photodegradation of Microplastics

Cited by 11 publications

References 179 publications

Enhanced Biocompatibility and Multifunctional Properties of Iron-Doped Zinc Oxide Nanoparticles for Applications

Enhanced Biocompatibility and Multifunctional Properties of Iron-Doped Zinc Oxide Nanoparticles for Applications

Magnetic Manganese‐Based Micromotors MnFe2O4@Fe3O4/graphite and Mn2O3@Fe2O3@Fe3O4/graphite for Organic Pollutant Degradation

Advanced and Smart Technology for Sustainable Management of Microfiber Waste

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Product

Resources

About

Magnetic Manganese‐Based Micromotors MnFe₂O₄@Fe₃O₄/graphite and Mn₂O₃@Fe₂O₃@Fe₃O₄/graphite for Organic Pollutant Degradation