Conversion of agricultural waste to porous hydrochar for non-metallic activation of persulfate to phenol degradation via non-radical-dominated processes: Singlet oxygen and electron transfer

Recently, non-radical oxidation was served as an efficient approach during pollutant degradation due to its excellent environmental applicability. However, designing a green and low-cost non-metallic catalyst to activate persulfate (PS) for removal of hazardous organic contaminants via non-radical-d...

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Published in:Journal of cleaner production 2023-09, Vol.419, p.138216, Article 138216
Main Authors: Qu, Jianhua, Tong, Wanying, Zhang, Jun, Ye, Kaiyin, Xiang, Linsong, Li, Ruolin, Wang, Di, Chen, Zihe, Hu, Qi, Zhang, Guangshan, Wang, Lei, Zhang, Ying
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Electron transfer
Hydrochar
Non-metallic catalyst
Reactive oxygen species
Water treatment
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cited_by cdi_FETCH-LOGICAL-c309t-5ac3f074242c2dde3bedc40f239a02bcc38a42813a2e289272a6ac4aa6a599083
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container_start_page 138216
container_title Journal of cleaner production
container_volume 419
creator Qu, Jianhua
Tong, Wanying
Zhang, Jun
Ye, Kaiyin
Xiang, Linsong
Li, Ruolin
Wang, Di
Chen, Zihe
Hu, Qi
Zhang, Guangshan
Wang, Lei
Zhang, Ying
description Recently, non-radical oxidation was served as an efficient approach during pollutant degradation due to its excellent environmental applicability. However, designing a green and low-cost non-metallic catalyst to activate persulfate (PS) for removal of hazardous organic contaminants via non-radical-dominated processes is still challenging. Herein, porous hydrochar (PHC) was synthesized with agricultural waste of corn straw (CS) as precursor and KHCO3 as pore-forming agent, which contained mesoporous structures with defects, thus facilitating phenol adsorption (117.14 mg/g). Moreover, 20 mg/L of phenol could achieve 100% removal at a wide pH range (7.0–11.0) within 10 min by PHC/PS system. The radical pathways induced by O·H and O2·− had certain effect on phenol removal, while non-radical pathways (1O2 and electron transfer process) played dominant contributions. Among them, 1O2 was produced from the reaction between surface functional groups on PHC and PS, and electron transfer process occurred from phenol to PS via PHC as the conductor. Whether under the interference of co-existing substances or in different water matrixes, the degradation efficiency of phenol could reach above 80%, exhibiting the excellent adaptability of PHC/PS system. This study proposed a potential resource utilization method of agricultural waste to prepare non-metallic catalyst for effective water remediation. [Display omitted] •Porous hydrochar is prepared as non-metallic catalyst for persulfate activation.•Adsorptive-catalytic capability of porous hydrochar for phenol removal is explored.•Functional groups and defects as active sites contribute to phenol degradation.•1O2 and electron transfer of non-radical pathways play dominant roles.•PHC/PS system exhibits great tolerance to extensive pH and co-existing constituents.
doi_str_mv 10.1016/j.jclepro.2023.138216
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subjects Electron transfer
Hydrochar
Non-metallic catalyst
Reactive oxygen species
Water treatment
title Conversion of agricultural waste to porous hydrochar for non-metallic activation of persulfate to phenol degradation via non-radical-dominated processes: Singlet oxygen and electron transfer
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