Unlocking High-Throughput Plasma-Catalytic Low-Temperature Oxidation of -Hexane over Single-Atom Ag/MnO Catalysts

Overview

Journal JACS Au

Publisher American Chemical Society

Date 2025 Jan 31

PMID 39886590

Authors

Zhiping Ye

Chuang Han

Shulin Yang

Yaolin Wang

Ke Wang

Anton Nikiforov

Jiade Wang

Rino Morent

Nathalie De Geyter

Xuming Zhang

Jun Chen

Mi Yan

Junhua Li

Xin Tu

Pengfei Xie

Affiliations

Soon will be listed here.

Abstract

The total oxidation of -hexane, a hazardous volatile organic compound (VOC) emitted by the pharmaceutical industry, presents a significant environmental challenge due to limited catalyst activity at low temperatures and poor stability at high temperatures. Here, we present a novel approach that overcomes these limitations by employing single-atom Ag/MnO catalysts coupled with nonthermal plasma (NTP). This strategy achieves exceptional performance in -hexane oxidation at low temperatures, demonstrating 96.3% -hexane removal and an energy yield of 74.1 g kW h with negligible byproduct formation (O < 5 ppm, NO < 20 ppm). In situ characterization of the plasma-catalytic system coupled with theoretical calculations revealed a synergistic mechanism for -hexane oxidation. Reactive species generated by the NTP initiate the breakdown of -hexane into smaller fragments. These fragments are then preferentially adsorbed onto the atomic Ag sites due to their favorable energetics, facilitating their subsequent oxidation. The incorporation of single Ag atoms not only enhances the selective adsorption of these NTP-generated intermediates but also accelerates the reaction kinetics. This work demonstrates the potential of single-atom catalysts coupled with NTP for efficient and environmentally friendly removal of VOCs at low temperatures. This approach offers a promising strategy for mitigating industrial air pollution and achieving cleaner air quality.

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