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用于从受污染环境水中去除无机污染物的可持续修复策略的原位功能化介孔二氧化硅

In situ Functionalized Mesoporous Silicas for Sustainable Remediation Strategies in Removal of Inorganic Pollutants from Contaminated Environmental Water.

作者信息

Kobylinska Natalia G, Kessler Vadim G, Seisenbaeva Gulaim A, Dudarko Oksana A

机构信息

A.V. Dumansky Institute of Colloid and Water Chemistry, NAS of Ukraine, blvd. Akad. Vernads'koho, 42, Kyiv 03680, Ukraine.

Department of Molecular Sciences, Swedish University of Agricultural Sciences, 75007 Uppsala, Sweden.

出版信息

ACS Omega. 2022 Jul 1;7(27):23576-23590. doi: 10.1021/acsomega.2c02151. eCollection 2022 Jul 12.

DOI:10.1021/acsomega.2c02151
PMID:35847252
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9280963/
Abstract

Low-cost mesoporous silicas of the SBA-15 family were prepared, aimed for removal of a broad spectrum of both cationic and anionic forms of hazardous metal pollutants (Cr(III, VI), Mn(II, VII), Pb(II), Cd(II), and Cu(II)) from environmental water. Series of mono- and bifunctional materials with immobilized ethylenediaminetriacetic acid (EDTA), primary amine (NH), and quaternary ammonium (QAS) groups were prepared in a cost-efficient one-step synthesis using two silica sources, low-cost sodium metasilicate (NaSiO 9HO) and the conventional source-tetraethylorthosilicate (TEOS). The functionalized SBA-15 samples obtained from both silica sources were highly ordered, as evidenced by TEM and SAXS data. All obtained materials were mesoporous with high surface area values of up to 745 m/g, pore volumes from 0.99 to 1.44 cm/g, and narrow pore distributions near 7 nm. The adsorption affinity of the EDTA-functionalized samples followed the common order Pb(II)> Cd(II)> Cu(II)> Cr(III)> Mn(II), which could be explained based on the Pearson theory. The highest adsorption capacities were observed for samples functionalized by EDTA groups using TEOS for synthesis (TEOS/EDTA): 195.6 mg/g for Pb(II), 111.2 mg/g for Cd(II), 58.7 mg/g for Cu(II), 57.7 mg/g for Cr(III), and 49.4 mg/g for Mn(II). Moreover, organic matter (humic acid up to 10 mg/L) and inorganic (Na(I), K(I), Mg(II), Ca(II), etc) macrocomponents present in environmental water had almost negligible effect on the removal of these cations. The NaSi/EDTA/NH sample revealed a better selectivity compared to the NaSiNH sample towards such species as Cr(III), Mn(II), Cd(II), and Cu(II). The chromate-ions uptake at pH 7.5 by the TEOS/QAS sample turned practically unaffected by the presence of doubly charged anions (CO , SO ). The content of functional groups on the surface of MS decreased only slightly (∼1-5%) after several regeneration cycles. The complete desorption of all heavy metal ions can be achieved using 1 mol/L EDTA solution. Reusability tests demonstrated the complete stability of the adsorbent for at least five to six consecutive adsorption/desorption cycles with no decrease in its adsorption characteristics compared to those obtained by 0.05 mol/L HNO treatments. The synthesized mesoporous materials were evaluated for removal of the heavy metal ions from drinking and different natural water samples, proving their potential as sustainable, effective, and cost-efficient adsorbents.

摘要

制备了SBA - 15家族的低成本介孔二氧化硅,旨在从环境水中去除多种阳离子和阴离子形式的有害金属污染物(Cr(III, VI)、Mn(II, VII)、Pb(II)、Cd(II)和Cu(II))。使用两种硅源,即低成本的偏硅酸钠(Na₂SiO₃·9H₂O)和传统的正硅酸四乙酯(TEOS),通过具有成本效益的一步合成法制备了一系列固定有乙二胺三乙酸(EDTA)、伯胺(NH₂)和季铵(QAS)基团的单功能和双功能材料。从两种硅源获得的功能化SBA - 15样品具有高度有序的结构,TEM和SAXS数据证明了这一点。所有获得的材料都是介孔的,具有高达745 m²/g的高比表面积值、0.99至1.44 cm³/g的孔体积以及接近7 nm的窄孔分布。EDTA功能化样品的吸附亲和力遵循常见顺序Pb(II)> Cd(II)> Cu(II)> Cr(III)> Mn(II),这可以根据皮尔逊理论来解释。使用TEOS合成的EDTA基团功能化样品(TEOS/EDTA)观察到最高吸附容量:Pb(II)为195.6 mg/g,Cd(II)为111.2 mg/g,Cu(II)为58.7 mg/g,Cr(III)为57.7 mg/g,Mn(II)为49.4 mg/g。此外,环境水中存在的有机物(高达10 mg/L的腐殖酸)和无机(Na(I)、K(I)、Mg(II)、Ca(II)等)大量成分对这些阳离子的去除几乎没有影响。与NaSiNH样品相比,NaSi/EDTA/NH样品对Cr(III)、Mn(II)、Cd(II)和Cu(II)等物种表现出更好的选择性。TEOS/QAS样品在pH 7.5时对铬酸根离子的吸收实际上不受双电荷阴离子(CO₃²⁻、SO₄²⁻)存在的影响。经过几次再生循环后,MS表面官能团的含量仅略有下降(约1 - 5%)。使用1 mol/L EDTA溶液可实现所有重金属离子的完全解吸。可重复使用性测试表明,吸附剂至少连续五到六个吸附/解吸循环具有完全稳定性,与0.05 mol/L HNO₃处理获得的吸附特性相比没有下降。对合成的介孔材料进行了从饮用水和不同天然水样中去除重金属离子的评估,证明了它们作为可持续、有效且具有成本效益的吸附剂的潜力。

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