A Kinetic Approach to Photomineralization of Methane in Air by Membranes Based on TiO2/WO3

化学与化工:英文版 Pub Date : 2020-07-28 DOI:10.17265/1934-7375/2020.03.001

Ignazio Renato Bellobono, F. Groppi, M. Sturini, A. Albini, F. Morazzoni

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Abstract

Photomineralization of methane in air (10.0-1,000 ppm (mass/volume) of C) at 100% relative humidity (dioxygen as oxygen donor), was systematically studied at 318 ± 3 K, in an annular laboratory-scale reactor, by photocatalytic membranes immobilising titanium dioxide and tungsten trioxide as co-photocatalysts. Kinetics of both substrate disappearance, to yield intermediates, and total organic carbon (TOC) disappearance, to yield carbon dioxide, were followed. A kinetic model was employed, from which, by a set of differential equations, four final optimised parameters, k1 and K1, k2 and K2, were calculated, able to fit the whole kinetic profile adequately. Modelling of quantum yields, as a function of substrate concentration and irradiance, as well as of concentration of photocatalysts, was carried out very satisfactorily. Kinetics of hydroxyl radicals reacting between themselves, leading to hydrogen peroxide, other than with substrate or intermediates leading to mineralization, were considered, paralleled by second competition kinetics involving superoxide radical anion. When using appropriate blends of the two photocatalysts, limiting quantum yields ∞ values increase considerably and approach the maximum allowable value for the investigated molecule, in a much wider range of irradiances than that shown by the single catalysts mainly at low irradiances. This may be interpreted by strong competition kinetics of superoxide radicals generated by the catalyst defects, in the corresponding range of high irradiances. By this way, operation at high irradiance values is possible, without losing any efficiency for the mineralization process.

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基于TiO2/WO3膜的空气中甲烷光电矿化动力学研究

在实验室规模的环型反应器中，在318±3 K的温度下，以二氧化钛和三氧化钨为共光催化剂，系统地研究了空气(10.0-1,000 ppm(质量/体积)C)中甲烷(质量/体积)的光矿化。研究了底物消失生成中间体和总有机碳(TOC)消失生成二氧化碳的动力学过程。采用动力学模型，通过一组微分方程，计算出最终优化参数k1和k1、k2和k2，能够充分拟合整个动力学剖面。模拟的量子产率，作为一个函数的底物浓度和辐照度，以及光催化剂的浓度，进行了非常令人满意。除了与底物或中间体反应导致矿化外，还考虑了羟基自由基之间反应导致过氧化氢的动力学，并考虑了涉及超氧自由基阴离子的第二次竞争动力学。当使用两种光催化剂的适当混合物时，限制量子产率的∞值显著增加，并接近所研究分子的最大允许值，在更宽的辐照范围内，比单一催化剂主要在低辐照度下显示的范围要大得多。这可能是由催化剂缺陷产生的超氧自由基在相应的高辐照度范围内的强竞争动力学来解释的。通过这种方式，可以在高辐照度值下操作，而不会损失矿化过程的任何效率。

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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化学与化工:英文版

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