Photooxidation and Virus Inactivation using TiO2(P25)–SiO2 Coated PET Film

Bulletin of Chemical Reaction Engineering & Catalysis Pub Date : 2022-06-23 DOI:10.9767/bcrec.17.3.14180.508-519

Chaowat Autthanit, Supachai Jadsadajerm, O. Núñez, Purim Kusonsakul, J. Luckanagul, Visarut Buranasudja, B. Jongsomjit, S. Praserthdam, P. Praserthdam

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引用次数: 3

Abstract

This study chemically modified PET film surface with P25 using silicate as a binder. Different P25–binder ratios were optimized for the catalyst performance. The modified samples were analyzed by scanning electron microscopy-energy-dispersive X-ray spectroscopy and Fourier transform infrared spectroscopy. Diffuse reflectance UV-vis spectra revealed significant reductions in the band gaps of the P25 solid precursor (3.20 eV) and the surface-modified PET–1.0Si–P25 (2.77 eV) with visible light. Accordingly, under visible light conditions, catalyst activity on the film will occur. Additionally, the film’s performance was evaluated using methylene blue (MB) degradation. Pseudo-first-order-rate constants (min−1), conversion percentages, and rates (µg.mL−1.gcat−1.h−1) were determined. The coated films were evaluated for viral Phi–X 174 inactivation and tested with fluorescence and UV-C light illumination, then log (N/N0) versus t plots (N = [virus] in plaque-forming units [PFUs]/mL) were obtained. The presence of nanosilica in PET showed a high adsorption ability in both MB and Phi–X 174, whereas the best performances with fluorescent light were obtained from PET–1.0Si–P25 and PET–P25–1.0Si–SiO2 equally. A 0.2-log virus reduction was obtained after 3 h at a rate of 4×106 PFU.mL−1.gcat−1.min−1. Additionally, the use of this film for preventing transmission by direct contact with surfaces and via indoor air was considered. Using UV light, the PET–1.0Si–P25 and PET–1.0Si–P25–SiO2 samples produced a 2.5-log inactivation after 6.5 min at a rate of 9.6×106 and 8.9×106 PFU.mL−1.gcat−1.min−1, respectively. Copyright © 2022 by Authors, Published by BCREC Group. This is an open access article under the CC BY-SA License (https://creativecommons.org/licenses/by-sa/4.0).

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TiO2(P25) -SiO2包覆PET膜的光氧化及病毒灭活

本研究以硅酸盐为粘结剂，用P25对PET薄膜表面进行化学改性。优化了不同的p25 -粘合剂配比对催化剂性能的影响。采用扫描电镜、能量色散x射线能谱和傅里叶变换红外光谱对改性后的样品进行了分析。漫反射紫外可见光谱显示，P25固体前驱体(3.20 eV)和表面改性PET-1.0Si-P25 (2.77 eV)在可见光下的带隙明显减小。因此，在可见光条件下，薄膜上就会发生催化剂活性。此外，采用亚甲基蓝(MB)降解法对膜的性能进行了评价。测定了伪一阶速率常数(min−1)、转化率(µg.mL−1.gcat−1.h−1)和转化率(µg.mL−1)。用荧光和UV-C光照检测包被膜对病毒Phi-X 174的失活效果，得到log (N/N0) vs . t图(N =[病毒]，以斑块形成单位[PFUs]/mL计算)。PET中纳米二氧化硅的存在对MB和Phi-X 174均表现出较高的吸附能力，而PET - 1.0 si - p25和PET - p25 - 1.0 si - sio2在荧光灯下的吸附性能最好。以4×106 PFU.mL−1.gcat−1.min−1的速率，在3 h后获得0.2 log的病毒减量。此外，还考虑使用这种薄膜来防止通过与表面直接接触和通过室内空气传播。使用UV光，PET-1.0Si-P25和PET-1.0Si-P25 - sio2样品在6.5 min后以9.6×106和8.9×106 PFU.mL−1.gcat−1的速率产生2.5 log失活。分钟−1,分别。版权所有©2022作者所有，BCREC集团出版。这是一篇基于CC BY-SA许可(https://creativecommons.org/licenses/by-sa/4.0)的开放获取文章。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Bulletin of Chemical Reaction Engineering & Catalysis

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