Morphology-Controlled WO3 for the Photocatalytic Oxidation of Methane to Methanol in Mild Conditions

Methane Pub Date : 2023-02-17 DOI:10.3390/methane2010008

Dumindu Premachandra, M. Heagy

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引用次数: 2

Abstract

Since WO3 is a relatively abundant metal oxide and features the ability to absorb in the visible spectrum, this non-toxic semiconductor is a promising photocatalyst among sustainable materials. These properties have delivered intriguing catalytic results in the conversion of methane to methanol; however, initial investigations indicate low photocatalytic efficiency resulting from fast recombination of photogenerated charges. To explore this aspect of inefficiency, five different morphologies of WO3 consisting of micron, nanopowder, rods, wires, and flowers were obtained and characterized. In addition, several electron capture agents/oxidizers were investigated as a means of improving the separation of photogenerated charges. The photocatalytic activity of different morphologies was assessed via CH3OH formation rates. Based on our results, WO3 flowers produced the highest methanol productivity (38.17 ± 3.24 µmol/g-h) when 2 mM H2O2 was present, which is approximately four times higher in the absence of H2O2. This higher methanol production has been attributed to the unique structure-related properties of the flower-like structure. Photoluminescence emission spectra and diffuse reflectance data reveal that flower structures are highly catalytic due to their reduced electron/hole recombination and multiple light reflections via petal-like hollow chambers.

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温和条件下甲烷光催化氧化制甲醇的形态控制WO3

由于WO3是一种相对丰富的金属氧化物，并且具有在可见光谱中吸收的能力，因此这种无毒半导体在可持续材料中是一种很有前途的光催化剂。这些特性在甲烷转化为甲醇的过程中产生了有趣的催化结果；然而，初步研究表明，光生电荷的快速复合导致光催化效率低。为了探索低效率的这一方面，获得并表征了由微米、纳米粉末、棒、线和花组成的五种不同形态的WO3。此外，还研究了几种电子捕获剂/氧化剂，作为改善光生电荷分离的一种手段。通过CH3OH的形成速率来评估不同形态的光催化活性。根据我们的结果，当存在2mM H2O2时，WO3花产生最高的甲醇生产力（38.17±3.24µmol/g-h），在没有H2O2的情况下，这大约高出四倍。这种较高的甲醇产量归因于花状结构的独特结构相关特性。光致发光发射光谱和漫反射数据表明，花结构由于其减少的电子/空穴复合和通过花瓣状空腔的多次光反射而具有高度催化性。

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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Methane

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