Redox-Active Polymers as Robust Electron-Shuttle Co-Catalysts for Fast Fe 3+ /Fe 2+ Circulation and Green Fenton Oxidation.
Hongyu ZhouJiali PengXiaoguang DuanHaoxiang YinBingkun HuangChenying ZhouShuang ZhongHeng ZhangPeng ZhouZhaokun XiongZhimin AoShaobin WangGang YaoBo LaiPublished in: Environmental science & technology (2023)
Accelerating the rate-limiting Fe 3+ /Fe 2+ circulation in Fenton reactions through the addition of reducing agents (or co-catalysts) stands out as one of the most promising technologies for rapid water decontamination. However, conventional reducing agents such as hydroxylamine and metal sulfides are greatly restricted by three intractable challenges: (1) self-quenching effects, (2) heavy metal dissolution, and (3) irreversible capacity decline. To this end, we, for the first time, introduced redox-active polymers as electron shuttles to expedite the Fe 3+ /Fe 2+ cycle and promote H 2 O 2 activation. The reduction of Fe 3+ mainly took place at active N-H or O-H bonds through a proton-coupled electron transfer process. As electron carriers, H atoms at the solid phase could effectively inhibit radical quenching, avoid metal dissolution, and maintain long-term reducing capacity via facile regeneration. Experimental and density functional theory (DFT) calculation results indicated that the activity of different polymers shows a volcano curve trend as a function of the energy barrier, highest occupied molecular orbital-lowest unoccupied molecular orbital (HOMO-LUMO) gap, and vertical ionization potential. Thanks to the appropriate redox ability, polyaniline outperforms other redox-active polymers (e.g., poypyrrole, hydroquinone resin, poly(2,6-diaminopyridine), and hexaazatrinaphthalene framework) with a highest iron reduction capacity up to 5.5 mmol/g, which corresponds to the state transformation from leucoemeraldine to emeraldine. Moreover, the proposed system exhibited high pollutant removal efficiency in a flow-through reactor for 8000 bed volumes without an obvious decline in performance. Overall, this work established a green and sustainable oxidation system, which offers great potential for practical organic wastewater remediation.
Keyphrases
- electron transfer
- metal organic framework
- density functional theory
- visible light
- wastewater treatment
- hydrogen peroxide
- aqueous solution
- heavy metals
- stem cells
- highly efficient
- molecular dynamics
- quantum dots
- mass spectrometry
- anaerobic digestion
- drinking water
- risk assessment
- health risk
- solar cells
- molecular docking
- sensitive detection