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利用镁渣合成多孔材料及其对水溶液中铅离子的吸附性能

Synthesis of Porous Materials Using Magnesium Slag and Their Adsorption Performance for Lead Ions in Aqueous Solution.

作者信息

Lu Guangjun, Han Jingang, Chen Ying, Xue Hongjiao, Qiu Ruifang, Zhou Xinxing, Ma Zhibin

机构信息

State Environmental Protection Key Laboratory of Efficient Utilization Technology of Coal Waste Resources, Institute of Resources and Environmental Engineering, Shanxi University, Taiyuan 030006, China.

出版信息

Materials (Basel). 2023 Nov 8;16(22):7083. doi: 10.3390/ma16227083.

DOI:10.3390/ma16227083
PMID:38005013
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10672025/
Abstract

Magnesium slag-based porous materials (MSBPM) were successfully synthesized using alkali activation and foaming methods as an effective adsorbent for Pb in solution. The effects of foaming agent type, foaming agent dosage, alkali dosage, and water glass modulus on the properties of the MSBPM were studied, and the micromorphology and porosity of the MSBPM were observed using microscopy. The influence of pH value, initial concentration, and adsorbent dosage on the Pb adsorption was investigated. The results showed that a porous material (MSBPM-HO) with high compressive strength (8.46 MPa) and excellent Pb adsorption capacity (396.11 mg·g) was obtained under the optimal conditions: a HO dosage of 3%, an alkali dosage of 9%, a water glass modulus of 1.3, and a liquid-solid ratio of 0.5. Another porous material (MSBPM-Al) with a compressive strength of 5.27 MPa and the Pb adsorption capacity of 424.89 mg·g was obtained under the optimal conditions: an aluminum powder dosage of 1.5‱, an alkali dosage of 8%, a water glass modulus of 1.0, and a liquid-solid ratio of 0.5. When the pH of the aqueous solution is 6 and the initial Pb concentrations are 200~500 mg·L, the MSBPM-HO and MSBPM-Al can remove more than 99% of Pb in the solution. The adsorption process of both materials followed the Langmuir isotherm model and pseudo-second-order kinetic model, indicating that the adsorption process was a single-molecule layer chemical adsorption.

摘要

采用碱激发和发泡法成功合成了镁渣基多孔材料(MSBPM),作为溶液中铅的有效吸附剂。研究了发泡剂类型、发泡剂用量、碱用量和水玻璃模数对MSBPM性能的影响,并通过显微镜观察了MSBPM的微观形貌和孔隙率。考察了pH值、初始浓度和吸附剂用量对铅吸附的影响。结果表明,在最佳条件下:双氧水用量3%、碱用量9%、水玻璃模数1.3、液固比0.5,得到了抗压强度高(8.46MPa)、铅吸附性能优异(396.11mg·g)的多孔材料(MSBPM-HO)。在最佳条件下:铝粉用量1.5‱、碱用量8%、水玻璃模数1.0、液固比0.5,得到了抗压强度为5.27MPa、铅吸附量为424.89mg·g的另一种多孔材料(MSBPM-Al)。当水溶液pH值为6、初始铅浓度为200~500mg·L时,MSBPM-HO和MSBPM-Al对溶液中铅的去除率均超过99%。两种材料的吸附过程均遵循Langmuir等温线模型和准二级动力学模型,表明吸附过程为单分子层化学吸附。

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