Photothermal catalytic oxidation of toluene over the Pt–Mn2O3/CN nanocomposite catalyst†

EES catalysis Pub Date : 2024-01-20 DOI:10.1039/D3EY00298E
Xiao Yu, Chuang Zhao, Lixia Yang, Jian Zhang and Chunlin Chen
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Abstract

The Pt–Mn2O3/CN catalyst formed through synthesis via a solvent-thermal method involves a synergistic combination of polymer CN and Pt nanoparticles loaded on Mn2O3 to catalyze the degradation of toluene. The composition incorporates Mn2O3 as the central element for photothermal conversion, CN as a uniformly dispersed matrix for Pt nanoparticles, and Pt as the catalytically active center, demonstrating significant efficacy. Particularly noteworthy is the discernible enhancement in the photothermal catalytic degradation capability of the Pt–Mn2O3/CN composite catalyst, specifically in the context of toluene. When subjected to light intensity of 300 mW cm−2 and a toluene concentration of 400 ppm, Pt–Mn2O3/CN achieves toluene conversion and CO2 mineralization rates of 99% and 80.9%, respectively. This improvement primarily stems from the Pt nanoparticles inducing a substantial presence of oxygen vacancies within the catalyst structure, thereby increasing the oxygen adsorption capacity and surface mobility. This, in turn, activates adsorbed oxygen species at the catalyst's interface. The adept utilization and conversion of solar irradiance for volatile organic compound (VOC) abatement underscore its potential as an environmentally friendly and renewable energy source.

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Pt-Mn2O3/CN 纳米复合催化剂对甲苯的光热催化氧化作用
通过溶剂热法合成的 Pt-Mn2O3/CN 催化剂是聚合物 CN 和负载在 Mn2O3 上的铂纳米粒子的协同组合,可催化甲苯降解。该组合物以 Mn2O3 作为光热转换的中心元素,以 CN 作为铂纳米粒子的均匀分散基质,以铂作为催化活性中心,显示出显著的功效。尤其值得注意的是,Pt-Mn2O3/CN 复合催化剂的光热催化降解能力明显增强,特别是在甲苯方面。当光照强度为 300 mW cm-2 和甲苯浓度为 400 ppm 时,Pt-Mn2O3/CN 的甲苯转化率和二氧化碳矿化率分别达到 99% 和 80.9%。这种改进主要源于铂纳米粒子在催化剂结构中诱导了大量氧空位的存在,从而提高了氧吸附能力和表面流动性。这反过来又激活了催化剂界面上吸附的氧物种。善于利用和转换太阳辐照度来减少挥发性有机化合物(VOC),凸显了其作为一种环境友好型可再生能源的潜力。
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