Investigation of boundary layer effect of intra-particle diffusion on methylene blue adsorption on activated carbon

IF 8 Q1 ENERGY & FUELS
Shivanthi P. Dharmarathna, N. Priyantha
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引用次数: 0

Abstract

Methylene blue (MB) is a model dye used in many adsorption studies, and it is chemisorbed on activated carbon (AC) adsorbent. The adsorption of an adsorbate by a natural adsorbent is a phenomenon where kinetics is often complex despite the necessity of having reliable information on such reactions which is much needed to predict the efficiency of industrial processes of which rate of adsorption plays an integral part. Such information is, at times, not available under different experimental conditions, limiting desired applications. The research reported herein was thus performed to investigate rate of adsorption of MB onto coconut shell activated carbon by fitting experimental data to kinetics and diffusion models. According to the regression analysis of linearized pseudo-order models applied for various experimental conditions, the pseudo first order (PFO) model is found to be best suited to describe the kinetics of the MB-AC system having rate constants in the range 0.0799 – 0.2437 min−1 under different experimental conditions at the ambient temperature. The rate constants determined through the PFO model at different solution temperatures are indicative of chemisorption of MB on AC surface. Application of the Webber and Morris intra-particle diffusion (IPD) model, which accounts for the boundary layer effect on mass transfer, indicates that adsorption kinetics may be controlled by both film diffusion and intra-particle diffusion sequentially, and that the thickness of the boundary layer on the AC surface, which is a measure of the intercept of the linearized Webber and Morris IPD model, is sensitive to experimental conditions. Consequently, experimental parameters would be able to control the adsorption behaviour of the MB-AC system, which can be investigated by monitoring the magnitude of the initial adsorption factor.

颗粒内扩散的边界层效应对亚甲蓝在活性炭上吸附作用的研究
亚甲基蓝(MB)是许多吸附研究中使用的一种模型染料,它被化学吸附在活性炭(AC)吸附剂上。天然吸附剂对吸附剂的吸附是一种动力学现象,通常比较复杂,尽管有必要获得有关此类反应的可靠信息。在不同的实验条件下,有时无法获得此类信息,从而限制了预期的应用。因此,本文报告的研究通过将实验数据拟合到动力学和扩散模型中,对甲基溴在椰壳活性炭上的吸附率进行了研究。根据对各种实验条件下线性化伪阶模型的回归分析,发现伪一阶(PFO)模型最适合描述甲基溴-活性炭系统的动力学,在环境温度下的不同实验条件下,其速率常数范围为 0.0799 - 0.2437 min-1。在不同的溶液温度下,通过 PFO 模型确定的速率常数表明甲基溴在 AC 表面具有化学吸附作用。Webber 和 Morris 粒子内扩散(IPD)模型考虑了边界层对传质的影响,该模型的应用表明,吸附动力学可能同时受薄膜扩散和粒子内扩散的先后控制,而且 AC 表面边界层的厚度(即线性化 Webber 和 Morris IPD 模型截距的测量值)对实验条件很敏感。因此,实验参数能够控制 MB-AC 系统的吸附行为,这可以通过监测初始吸附系数的大小来研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Energy nexus
Energy nexus Energy (General), Ecological Modelling, Renewable Energy, Sustainability and the Environment, Water Science and Technology, Agricultural and Biological Sciences (General)
CiteScore
7.70
自引率
0.00%
发文量
0
审稿时长
109 days
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