Sugarcane bagasse-derived biochar modified by alkali for enriching surface functional groups to effectively treat ammonium-contaminated water.

IF 3.2 3区 环境科学与生态学 Q3 ENGINEERING, ENVIRONMENTAL Environmental Geochemistry and Health Pub Date : 2024-10-14 DOI:10.1007/s10653-024-02248-0
Lan Huong Nguyen, Van-Phuoc Kha, Nam Van Thai
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Abstract

In this study, sugarcane bagasse (SB), which was preliminarily treated with H3PO4, was utilized to produce biochar (SB-BC). The SB-BC was subsequently modified with KOH to enrich oxygen-containing functional groups (OCFGs) for the enhanced adsorption of NH4+ from wastewater. Batch tests revealed that KOH-modified SB-BC (SB-MBC) increased the maximum Langmuir adsorption capacity of NH4+ by approximately twofold, from 27.1 mg/g for SB-BC to 53.1 mg/g for SB-MBC. The optimal operational conditions for NH4+ adsorption onto SB-MBC were pH of 7.0 and a biochar dose of 3.0 g/L for the removal of 50 mg/L NH4+ at room temperature (25 ± 2 °C) over 180 min of contact. The enhanced adsorption capacity of NH4+ onto SB-MBC was due to the important contribution of the OCFGs enriched on the surface of biochar, which was increased by about fourfold, after being modified by KOH. The NH4+ adsorption dynamics were better fitted by the Elovich and the NH4+ adsorption isotherms were better described by Langmuir and Sips models, showing that the adsorption process was dominated by monolayer chemisorption. The properties of the adsorption materials before and after adsorption of NH4+ confirmed that cation exchange, electrostatic attraction and surface complexation were the main mechanisms controlling the adsorption process. The desorption and reusability tests of NH4+-saturated SB-MBC revealed that NH4+ adsorption slightly decreased after three successive sorption‒desorption cycles. The findings suggested that SB-MBC is a promising and feasible adsorbent for the effective treatment of NH4+-contaminated water sources. Future work should conduct tests for treatment of NH4+-rich real wastewater and utilize NH4+-saturated SB-MBC as slow releasing fertilizer for plants growth.

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用碱改性甘蔗渣衍生生物炭,以丰富表面官能团,从而有效处理氨污染水。
在本研究中,甘蔗渣(SB)经 H3PO4 初步处理后被用于生产生物炭(SB-BC)。随后用 KOH 对 SB-BC 进行改性,使其富含含氧官能团 (OCFG),从而增强对废水中 NH4+ 的吸附。批量测试表明,KOH 改性的 SB-BC (SB-MBC) 对 NH4+ 的最大兰姆吸附容量提高了约两倍,从 SB-BC 的 27.1 mg/g 提高到 SB-MBC 的 53.1 mg/g。SB-MBC 吸附 NH4+ 的最佳操作条件是:pH 值为 7.0,生物炭剂量为 3.0 g/L,在室温(25 ± 2 °C)下接触 180 分钟,去除 50 mg/L NH4+。NH4+ 在 SB-MBC 上的吸附能力增强是由于生物炭表面富集的 OCFGs 的重要贡献,经 KOH 改性后,OCFGs 增加了约四倍。Elovich 模型较好地拟合了 NH4+ 的吸附动力学,Langmuir 和 Sips 模型较好地描述了 NH4+ 的吸附等温线,表明吸附过程以单层化学吸附为主。吸附材料在吸附 NH4+ 前后的性质证实,阳离子交换、静电吸引和表面络合是控制吸附过程的主要机制。对饱和 NH4+ 的 SB-MBC 进行的解吸和可重复使用性测试表明,在连续三次吸附-解吸循环后,NH4+ 的吸附量略有下降。研究结果表明,SB-MBC 是一种有效处理 NH4+污染水源的前景广阔且可行的吸附剂。未来的工作应针对富含 NH4+ 的实际废水处理进行试验,并利用 NH4+ 饱和的 SB-MBC 作为植物生长的缓释肥料。
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来源期刊
Environmental Geochemistry and Health
Environmental Geochemistry and Health 环境科学-工程:环境
CiteScore
8.00
自引率
4.80%
发文量
279
审稿时长
4.2 months
期刊介绍: Environmental Geochemistry and Health publishes original research papers and review papers across the broad field of environmental geochemistry. Environmental geochemistry and health establishes and explains links between the natural or disturbed chemical composition of the earth’s surface and the health of plants, animals and people. Beneficial elements regulate or promote enzymatic and hormonal activity whereas other elements may be toxic. Bedrock geochemistry controls the composition of soil and hence that of water and vegetation. Environmental issues, such as pollution, arising from the extraction and use of mineral resources, are discussed. The effects of contaminants introduced into the earth’s geochemical systems are examined. Geochemical surveys of soil, water and plants show how major and trace elements are distributed geographically. Associated epidemiological studies reveal the possibility of causal links between the natural or disturbed geochemical environment and disease. Experimental research illuminates the nature or consequences of natural or disturbed geochemical processes. The journal particularly welcomes novel research linking environmental geochemistry and health issues on such topics as: heavy metals (including mercury), persistent organic pollutants (POPs), and mixed chemicals emitted through human activities, such as uncontrolled recycling of electronic-waste; waste recycling; surface-atmospheric interaction processes (natural and anthropogenic emissions, vertical transport, deposition, and physical-chemical interaction) of gases and aerosols; phytoremediation/restoration of contaminated sites; food contamination and safety; environmental effects of medicines; effects and toxicity of mixed pollutants; speciation of heavy metals/metalloids; effects of mining; disturbed geochemistry from human behavior, natural or man-made hazards; particle and nanoparticle toxicology; risk and the vulnerability of populations, etc.
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