Synergistic Co-pyrolysis of Fenton sludge biochar for fluoride removal: Strategy optimization and cooperative adsorption mechanisms

IF 6.7 2区工程技术 Q1 ENGINEERING, CHEMICAL

Journal of water process engineering Pub Date : 2025-09-12 DOI:10.1016/j.jwpe.2025.108717

Siqi Tong , Lei Zhang , Xuemin Yu , Guangbing Liu , Haibo Xu , Weijing Liu , Jinyou Shen , Yi Wang

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Abstract

Fluoride-containing wastewater posed significant environmental and health risks, and the high costs of current defluoridation adsorbents highlight the pressing need for cost-effective solutions. To achieve the advanced treatment of fluoride-containing wastewater and the resource utilization of solid waste, a pyrolytic-hydrothermal carbon adsorbent was developed from Fenton sludge (FS) and rice straw (RS). FS/RS-1:2BC, synthesized at 600 °C pyrolysis and 200 °C hydrothermal treatment with a 1:2 mass ratio, exhibited the highest fluoride ions (F⁻) adsorption capacity of 10.57 mg g⁻¹. Physicochemical characterization revealed FS/RS-1:2BC consisted of porous graphitic carbon from RS and α-Fe₂O₃ from FS, with abundant oxygen-containing groups and a large surface area for F⁻ adsorption. Adsorption kinetics and thermodynamic fitting indicated the adsorption of F⁻ was primarily relied on chemical interactions (chemical precipitation, ligand complexation, ion exchange, electrostatic attraction) between F⁻ and the homogeneous monolayer surface, with physical adsorption and intraparticle diffusion as secondary mechanisms. FS/RS-1:2BC exhibited excellent stability and applicability, with a broad pH acceptance range (pH 3.5–8). It maintained 9.58 mg g⁻¹ adsorption capacity under weakly alkaline and achieved around 90 % adsorption efficiency in coexisting anions. Regeneration experiments indicated that FS/RS-1:2BC retained 81.9 % adsorption capacity after five regeneration cycles. The development of FS/RS-1:2BC not only provided a cost-effective adsorbent for low-concentration fluoride removal from tailwater but also established a new approach for resource utilization of solid wastes.

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Fenton污泥生物炭协同热解除氟：策略优化及协同吸附机理

含氟废水构成重大的环境和健康风险，目前除氟吸附剂的高成本突出表明迫切需要具有成本效益的解决办法。为实现含氟废水的深度处理和固体废物资源化利用，以Fenton污泥（FS）和稻秆（RS）为原料，研制了热解水热碳吸附剂。FS/RS-1:2BC在600℃热解和200℃水热条件下以1:2的质量比合成，对氟离子（F−）的吸附量最高，为10.57 mg g−1。理化表征表明FS/RS-1:2 bc由RS的多孔石墨碳和FS的α-Fe₂O₃组成，具有丰富的含氧基团和较大的吸附F−表面积。吸附动力学和热力学拟合表明，F -的吸附主要依赖于F -与均匀单层表面的化学相互作用（化学沉淀、配体络合、离子交换、静电吸引），其次是物理吸附和颗粒内扩散。FS/RS-1:2BC具有良好的稳定性和适用性，pH值接受范围广（pH值为3.5 ~ 8）。在弱碱性条件下保持9.58 mg g−1的吸附量，在阴离子共存条件下吸附效率达到90%左右。再生实验表明，经过5次再生后，FS/RS-1:2BC的吸附容量仍保持在81.9%。FS/RS-1:2BC的研制不仅为尾水中低浓度氟的脱除提供了一种经济高效的吸附剂，而且为固体废物资源化利用开辟了一条新的途径。

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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