Name: Biomedical Response of Photoactive SiO2-Zn@Fe2O3 Nanofibers (en Inglés)
Price: 51720.00 CLP
Availability: InStock
Author: Haq, Zia Ul ; Nazir, Sadia ; Tahir, Kamran
ISBN: 9781636483061

portada Biomedical Response of Photoactive SiO2-Zn@Fe2O3 Nanofibers (en Inglés)

Formato

Libro Físico

Autor

Editorial

Idioma

Inglés

N° páginas

Encuadernación

Tapa Blanda

Dimensiones

22.9 x 15.2 x 0.2 cm

Peso

0.06 kg.

ISBN13

9781636483061

Categorías

Química

Biomedical Response of Photoactive SiO2-Zn@Fe2O3 Nanofibers (en Inglés)

Zia Ul Haq (Autor) · Sadia Nazir (Autor) · Kamran Tahir (Autor) · Eliva Press · Tapa Blanda

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Origen: Estados Unidos (Costos de importación incluídos en el precio)

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Reseña del libro "Biomedical Response of Photoactive SiO2-Zn@Fe2O3 Nanofibers (en Inglés)"

Here, in the presence of Fe3O4 nano-fibers, we prepared SiO2-Zn@Fe2O3 hybrid Nano-fibers through a novel and simple one-pot redox reaction between ZnSO4 & SiO2. The Fe3O4 exterior nano-fibers would be homogenously covered by SiO2 coating to arrange a distinctive core-shell construction and then Zn nanoparticles are intercalated in the covering of SiO2. The synthesized nanofibers were tested for photodegradation of methylene blue (MB). The result showed that 99% MB was degraded in 60 minutes. Furthermore, the antibacterial potential of SiO2-Zn@Fe2O3 nanofibers was tested against E. coli and S. aureus bacteria both in light and dark. The impact of different analysis such as Reactive oxygen species (ROS) analysis, irradiation ef-fect on bacterial inhibition, concentration effect of SiO2-Zn@Fe2O3 nanofibers and reduc-tion of DPPH studied. The findings clearly demonstrate that ROS is produced in the presence of SiO2-Zn@Fe2O3 nanofibers in bacterial cells and is responsible for their inhibition. Findings have shown that synthesized nanostructures can also increase the stability of DPPH radicals with increasing concentrations of nanomaterials, making them a strong candidate for DPPH reduction. The overall results show that the efficacy of SiO2-Zn@Fe2O3 nanofibers for inhibition was more pronounced than that of individual iron oxides.