Unraveling the synergistic cobalt-nitrogen cooperation in biochar for enhanced peroxymonosulfate activation: Mechanistic insights into nitrogen configuration-dependent radical pathways and direct electron transfer

IF 6.3 2区工程技术 Q1 ENGINEERING, CHEMICAL

Journal of water process engineering Pub Date : 2025-07-15 DOI:10.1016/j.jwpe.2025.108326

Junhui Wang , Caimei Lu , Kun Liu , Jianlin Lv , Jingyuan Yan , Zuofang Yao , Zisong Xu , Yingqi Lu , Zhangfa Tong , Hanbing Zhang

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引用次数: 0

Abstract

The persulfate-based advanced oxidation processes employing biochar catalysts present a promising strategy for refractory organic pollutant removal, yet the interfacial reaction mechanisms governing pollutant degradation remain insufficiently elucidated. Herein, we innovatively developed a cobalt‑nitrogen co-embedded hierarchical porous biochar (Co-N@BC) through impregnation and pyrolysis of waste fir sawdust, demonstrating exceptional peroxymonosulfate (PMS) activation capability for chloroquine phosphate (CQP) degradation. Systematic investigations revealed that the Co-N@BC/PMS system achieved 97 % CQP removal within 45 min (k_obs = 0.061 min⁻¹) accompanied by 72 % total organic carbon reduction, outperforming conventional persulfate activation systems. The electrochemical analysis confirmed the formation of a metastable reactive complex between Co-N@BC and PMS, with its open-circuit potential change (ΔE = 0.27 V) being significantly higher than that of the nitrogen-doped system (ΔE = 0.17 V). Distinguished from the conventional radical-dominated mechanism, the study confirms the existence of a unique dual-pathway synergistic effect in the catalytic process: (1) Radical pathways dominated by surface-bound SO₄⁻• and •OH through Co²⁺/Co³⁺ redox cycling; (2) Non-radical pathways featuring ¹O₂ generation via surface group-mediated PMS activation and direct electron transfer through Co-N@BC-PMS* metastable complexes. Notably, we unveiled that the formed Co-N@BC-PMS* complexes function as interfacial electron-transfer mediators, simultaneously enhancing the efficiency of PMS activation and accelerating pollutant oxidation through interfacial-confined redox reactions. The engineered catalyst demonstrated remarkable environmental robustness, maintaining more than 90 % efficiency across four cycles, and exhibited broad pH adaptability (pH 3–11, less than 5 % variation). This study offers a new insight into the dynamic interactions between the multifunctional active sites of biochar and the mechanisms of persulfate activation. It also establishes a sustainable framework for converting waste biomass into highly efficient environmental catalysts.

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揭示生物炭中钴-氮协同合作增强过氧单硫酸盐活化：氮构型依赖自由基途径和直接电子转移的机制见解

以过硫酸盐为基础，采用生物炭催化剂的高级氧化工艺是去除难降解有机污染物的一种很有前途的策略，但控制污染物降解的界面反应机制尚未得到充分阐明。在此，我们创新地通过浸渍和热解废杉木木屑开发了钴-氮共包埋的分层多孔生物炭（Co-N@BC），展示了卓越的过氧单硫酸盐（PMS）活化能力，以降解磷酸氯喹（CQP）。系统研究表明，Co-N@BC/PMS系统在45分钟内达到97%的CQP去除率（kobs = 0.061 min−1），同时总有机碳减少72%，优于传统的过硫酸盐活化系统。电化学分析证实Co-N@BC与PMS之间形成亚稳态反应配合物，其开路电位变化（ΔE = 0.27 V）明显高于氮掺杂体系（ΔE = 0.17 V）。与传统的自由基主导机制不同，本研究证实了在催化过程中存在独特的双途径协同效应：(1)自由基途径以表面结合的SO4−•和•OH为主，通过Co2+/Co3+氧化还原循环；(2)通过表面基团介导的PMS活化和通过Co-N@BC-PMS*亚稳态配合物的直接电子转移产生1O2的非自由基途径。值得注意的是，我们发现形成的Co-N@BC-PMS*配合物作为界面电子转移介质，同时提高了PMS的激活效率，并通过界面限制的氧化还原反应加速了污染物的氧化。该工程催化剂表现出显著的环境鲁棒性，在四个循环中保持90%以上的效率，并表现出广泛的pH适应性（pH 3-11，变化小于5%）。该研究为生物炭多功能活性位点之间的动态相互作用和过硫酸盐活化机制提供了新的认识。它还建立了将废弃生物质转化为高效环境催化剂的可持续框架。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of water process engineering Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

10.70

自引率

8.60%

发文量

846

审稿时长

24 days

期刊介绍： The Journal of Water Process Engineering aims to publish refereed, high-quality research papers with significant novelty and impact in all areas of the engineering of water and wastewater processing . Papers on advanced and novel treatment processes and technologies are particularly welcome. The Journal considers papers in areas such as nanotechnology and biotechnology applications in water, novel oxidation and separation processes, membrane processes (except those for desalination) , catalytic processes for the removal of water contaminants, sustainable processes, water reuse and recycling, water use and wastewater minimization, integrated/hybrid technology, process modeling of water treatment and novel treatment processes. Submissions on the subject of adsorbents, including standard measurements of adsorption kinetics and equilibrium will only be considered if there is a genuine case for novelty and contribution, for example highly novel, sustainable adsorbents and their use: papers on activated carbon-type materials derived from natural matter, or surfactant-modified clays and related minerals, would not fulfil this criterion. The Journal particularly welcomes contributions involving environmentally, economically and socially sustainable technology for water treatment, including those which are energy-efficient, with minimal or no chemical consumption, and capable of water recycling and reuse that minimizes the direct disposal of wastewater to the aquatic environment. Papers that describe novel ideas for solving issues related to water quality and availability are also welcome, as are those that show the transfer of techniques from other disciplines. The Journal will consider papers dealing with processes for various water matrices including drinking water (except desalination), domestic, urban and industrial wastewaters, in addition to their residues. It is expected that the journal will be of particular relevance to chemical and process engineers working in the field. The Journal welcomes Full Text papers, Short Communications, State-of-the-Art Reviews and Letters to Editors and Case Studies