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用于染料去除的椰壳高性能活性炭:等温线与热力学研究

High-performance activated carbon from coconut shells for dye removal: study of isotherm and thermodynamics.

作者信息

Saleem Junaid, Moghal Zubair Khalid Baig, Pradhan Snigdhendubala, McKay Gordon

机构信息

Division of Sustainable Development, College of Science and Engineering, Hamad Bin Khalifa University, Qatar Foundation Doha Qatar

Center for Advanced Materials, Qatar University Qatar

出版信息

RSC Adv. 2024 Oct 24;14(46):33797-33808. doi: 10.1039/d4ra06287f. eCollection 2024 Oct 23.

DOI:10.1039/d4ra06287f
PMID:39450059
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11500064/
Abstract

This study investigates the production of high-performance activated carbon (AC) from coconut shells (CS) through acid and base activation processes, along with pre- and post-functionalization of the biochar, aiming to effectively remove dyes from aqueous solutions. The resulting AC exhibited outstanding adsorption capabilities, with the Langmuir model providing a good fit to the experimental data. Maximum adsorption capacities were observed at different temperatures: 805 mg g at 298 K, 904 mg g at 318 K, and 1000 mg g at 338 K for NaOH-activated AC, and 252 mg g at 298 K, 295 mg g at 318 K, and 305 mg g at 338 K for HSO-activated AC. The presence of active sites and functional groups on the surface of AC facilitated dye adsorption. The influence of various parameters, including adsorbent dosage, dye concentration, pH, and temperature, on the adsorption process were also examined, identifying the ideal conditions for dye removal. Thermodynamic analysis confirmed the endothermic nature of the adsorption process, with higher temperatures leading to increased adsorption capacities. Overall, the research highlights the potential of various activation routes for the production of high-value AC as a sustainable and effective adsorbent for dye removal from wastewater.

摘要

本研究通过酸和碱活化工艺,以及生物炭的预功能化和后功能化,研究了从椰壳(CS)制备高性能活性炭(AC),旨在有效去除水溶液中的染料。所得的活性炭表现出出色的吸附能力,朗缪尔模型与实验数据拟合良好。在不同温度下观察到最大吸附容量:对于NaOH活化的活性炭,在298K时为805mg/g,在318K时为904mg/g,在338K时为1000mg/g;对于HSO活化的活性炭,在298K时为252mg/g,在318K时为295mg/g,在338K时为305mg/g。活性炭表面活性位点和官能团的存在促进了染料吸附。还研究了吸附剂用量、染料浓度、pH值和温度等各种参数对吸附过程的影响,确定了染料去除的理想条件。热力学分析证实了吸附过程的吸热性质,较高的温度导致吸附容量增加。总体而言,该研究突出了各种活化途径在生产高价值活性炭方面的潜力,这种活性炭可作为一种可持续且有效的吸附剂用于去除废水中的染料。

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