Deep Oxidation of Chlorinated VOCs by Efficient Catalytic Peroxide Activation over Nanoconfined Co@NCNT Catalysts.
Xiaowen XieFei XiaoSihui ZhanMingshan ZhuYongjie XiangHuanran ZhongHaibao HuangPublished in: Environmental science & technology (2024)
The catalytic removal of chlorinated VOCs (CVOCs) in gas-solid reactions usually suffers from chlorine-containing byproduct formation and catalyst deactivation. AOP wet scrubber has recently attracted ever-increasing interest in VOC treatment due to its advantages of high efficiency and no gaseous byproduct emission. Herein, the low-valence Co nanoparticles (NPs) confined in a N-doped carbon nanotube (Co@NCNT) were studied to activate peroxymonosulfate (PMS) for efficient CVOC removal in a wet scrubber. Co@NCNT exhibited unprecedented catalytic activity, recyclability, and low Co ion leakage (0.19 mg L -1 ) for chlorobenzene degradation in a very wide pH range (3-11). The chlorobenzene removal efficiency was kept stable above 90% over Co@NCNT, much higher than that of nonconfined Co@NCNS (45%). The low-valence Co NPs achieved a continuous electron redox cycling (Co 0 /Co 2+ → Co 3+ → Co 0 /Co 2+ ) and greatly promoted the O-O bond dissociation of PMS with the least energy (0.83 eV) inside the channel of Co@NCNT to form abundant HO • and SO 4 •- . Thus, the deep oxidation of chlorobenzene was achieved without any biphenyl byproducts from the coupling reaction. This study provided a new avenue for designing novel nanoconfined catalysts with outstanding activity, paving the way for the deep oxidation of CVOC waste gas via AOP wet scrubber.
Keyphrases
- electron transfer
- highly efficient
- room temperature
- high efficiency
- carbon nanotubes
- metal organic framework
- visible light
- hydrogen peroxide
- drinking water
- carbon dioxide
- quantum dots
- heavy metals
- high intensity
- polycyclic aromatic hydrocarbons
- gas chromatography
- mass spectrometry
- gold nanoparticles
- signaling pathway
- municipal solid waste
- pi k akt
- tandem mass spectrometry
- reduced graphene oxide
- solar cells
- simultaneous determination