甲基红和亚甲基蓝在生物炭上的同步吸附及高浓度下的平衡建模

Simultaneous adsorption of methyl red and methylene blue onto biochar and an equilibrium modeling at high concentration.

作者信息

Ding Guanyu, Wang Buyun, Chen Lingyu, Zhao Shuangjiao

机构信息

School of Environmental Engineering, Wuhan Textile University, Wuhan, 430073, PR China.

出版信息

Chemosphere. 2016 Nov;163:283-289. doi: 10.1016/j.chemosphere.2016.08.037. Epub 2016 Aug 18.

DOI:10.1016/j.chemosphere.2016.08.037

PMID:27543677

Abstract

Methyl red, methylene blue and biochar were used to investigate simultaneous adsorption of dyes onto low-cost adsorbent at different concentrations combinations. Langmuir mixed model could describe the adsorption well at low concentrations. However, it could not describe the adsorption anymore when concentrations of methyl red and methylene blue were higher than 255 and 300 mg L(-1) respectively with 0.5 g L(-1) biochar loading. A new model on the interaction among adsorbed adsorbates at equilibrium was developed. It could describe the adsorption at high concentrations well. According to the experimental results, interaction among dyes molecules would replace the competition onto adsorbent to be the main factor influencing adsorption when amount of adsorbed adsorbates were higher than those required to form a monolayer on all the adsorbing sites of adsorbent. The model was further verified by adsorption with other solute such as glucose or NaCl in solution.

摘要

使用甲基红、亚甲基蓝和生物炭研究了在不同浓度组合下染料在低成本吸附剂上的同步吸附情况。在低浓度时，朗缪尔混合模型能很好地描述吸附过程。然而，当生物炭负载量为0.5 g L⁻¹时，若甲基红和亚甲基蓝的浓度分别高于255和300 mg L⁻¹，该模型就无法再描述吸附情况了。于是开发了一种关于平衡时吸附质之间相互作用的新模型。它能很好地描述高浓度下的吸附情况。根据实验结果，当吸附质的量高于在吸附剂所有吸附位点上形成单分子层所需的量时，染料分子之间的相互作用将取代对吸附剂的竞争，成为影响吸附的主要因素。该模型通过在溶液中用其他溶质如葡萄糖或氯化钠进行吸附进一步得到了验证。

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甲基红和亚甲基蓝在生物炭上的同步吸附及高浓度下的平衡建模

Simultaneous adsorption of methyl red and methylene blue onto biochar and an equilibrium modeling at high concentration.

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