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Electronic interaction between biochar and montmorillonite toward enhanced peroxymonosulfate activation
Abstract Biochar works as the catalyst for activating peroxymonosulfate (PMS) to produce highly oxidizing radicals to remove organic contaminants from wastewater, but its activity requires further improvement. Recent research demonstrates that the PMS activation performance of biochar is closely related to the oxygen-containing functional groups (OFGs). Therefore, biochar/montmorillonite (BC/Mt) composites are designed for activating PMS toward degrading tetracycline. The negative charge of Mt. induced the electron transfer form Mt. to BC, which increases the nucleophilicity of CO groups that promote the activation of PMS to •OH and SO4 •− radicals. Meanwhile, the pyrolysis path of rice straw is tuned by Mt., and the amount of COO groups is increased from 8.99% to 9.79% that promotes the generation of 1O2. Moreover, electron paramagnetic resonance and quenching experiments reveal that the activation mechanism of PMS by the BC/Mt. is comprised of both the radical and the non-radical pathway. Consequently, the tetracycline degradation kinetics using the optimized BC/Mt. (0.117 min−1) is higher than either bare BC (0.0866 min−1) or bare Mt. (0.0258 min−1), highlighting the significance of the rational design of electrocatalysts toward the enhanced catalytic chemistry. This work provides a facile route to improve the catalytic performance of biochar by hybridizing with clay minerals and is of great significance to promote the practical application of PMS-based advanced oxidation processes.
Graphical abstract Display Omitted
Highlights Biochar/montmorillonite composites are designed for peroxymonosulfate activation. The composites exhibit substantially enhanced reaction kinetics. Oxygen-containing functional groups in biochar are modulated by montmorillonite. The electronic interaction is a primary reason for the enhanced activation kinetics.
Electronic interaction between biochar and montmorillonite toward enhanced peroxymonosulfate activation
Abstract Biochar works as the catalyst for activating peroxymonosulfate (PMS) to produce highly oxidizing radicals to remove organic contaminants from wastewater, but its activity requires further improvement. Recent research demonstrates that the PMS activation performance of biochar is closely related to the oxygen-containing functional groups (OFGs). Therefore, biochar/montmorillonite (BC/Mt) composites are designed for activating PMS toward degrading tetracycline. The negative charge of Mt. induced the electron transfer form Mt. to BC, which increases the nucleophilicity of CO groups that promote the activation of PMS to •OH and SO4 •− radicals. Meanwhile, the pyrolysis path of rice straw is tuned by Mt., and the amount of COO groups is increased from 8.99% to 9.79% that promotes the generation of 1O2. Moreover, electron paramagnetic resonance and quenching experiments reveal that the activation mechanism of PMS by the BC/Mt. is comprised of both the radical and the non-radical pathway. Consequently, the tetracycline degradation kinetics using the optimized BC/Mt. (0.117 min−1) is higher than either bare BC (0.0866 min−1) or bare Mt. (0.0258 min−1), highlighting the significance of the rational design of electrocatalysts toward the enhanced catalytic chemistry. This work provides a facile route to improve the catalytic performance of biochar by hybridizing with clay minerals and is of great significance to promote the practical application of PMS-based advanced oxidation processes.
Graphical abstract Display Omitted
Highlights Biochar/montmorillonite composites are designed for peroxymonosulfate activation. The composites exhibit substantially enhanced reaction kinetics. Oxygen-containing functional groups in biochar are modulated by montmorillonite. The electronic interaction is a primary reason for the enhanced activation kinetics.
Electronic interaction between biochar and montmorillonite toward enhanced peroxymonosulfate activation
Yuan, Kehui (Autor:in) / Gao, Chao (Autor:in) / Zhao, Guoqiang (Autor:in) / Yang, Huaming (Autor:in)
Applied Clay Science ; 249
13.01.2024
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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