POTENTIAL VALORISATION OF PROTOBIND 1000 AS ADSORBENT FOR Pb2+ AND Zn2+

Journal of Applied Life Sciences and Environment Pub Date : 1900-01-01 DOI:10.46909/alse-551044

A. Trofin, Elena Ungureanu, L. Trincă, M. Fortună, Diana Beatrice Eperjessy

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引用次数: 1

Abstract

The adsorption of metal ions from increasing concentrations in aqueous solutions by modified straw lignin Protobind 1000 was studied. The effect of metallic ion concentrations (from 20.72 to 207.2 mg·L-1 for Pb2+ and from 6.538 to 65.38 mg·L-1 for Zn2+) and contact time (30, 60 and 90 minutes) were studied at pH = 6 and 200C. Langmuir and Freundlich isotherm equations were applied to assess equilibrium data and the kinetics of the adsorption processes were analysed using Lagergren pseudo first order and Ho&McKay pseudo second order models. The results show that the adsorption processes reached equilibrium after 90 minutes, but similar values were registered after 60 minutes. The Freundlich isotherm described the process better, denoting chemisorption with the formation of ion-lignin complex structures. The Ho&McKay model fit the adsorption data better with regression coefficients equal to 1 compared to the Lagergren model, where the regression factors varied between 0.72 and 0.95. For the maximum concentration of lead solution and the longest adsorption time of 90 minutes, the Ho&McKay model predicted an equilibrium capacity qe of 13.1406 mg·g-1 compared to the 13.1398 mg·g-1 obtained. For zinc adsorption, the same maximum concentration and time were considered, and the pseudo-second order model predicted a qe of 12.6743 mg·g-1 compared to the obtained value of 12.6714 mg·g-1. The uptake of lead was greater on 0.15 g of adsorbent (a maximum of 27.23 mg·g-1) than the zinc uptake (a maximum of 8.28 mg·g-1), for all analysed concentrations.

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原结合物1000作为Pb2+和Zn2+吸附剂的潜在价值

研究了改性秸秆木质素Protobind 1000对水溶液中金属离子的吸附性能。在pH = 6和200C条件下，研究了金属离子浓度(Pb2+为20.72 ~ 207.2 mg·L-1, Zn2+为6.538 ~ 65.38 mg·L-1)和接触时间(30、60、90 min)对金属离子的影响。采用Langmuir和Freundlich等温线方程评估平衡数据，采用Lagergren伪一阶和Ho&McKay伪二阶模型分析吸附过程动力学。结果表明，吸附过程在90分钟后达到平衡，但在60分钟后达到相似的值。Freundlich等温线更好地描述了这一过程，表明化学吸附与离子-木质素复合物结构的形成。与回归系数为1的Lagergren模型相比，Ho&McKay模型对吸附数据的拟合效果更好，回归系数在0.72 ~ 0.95之间。对于铅溶液的最大浓度和最长吸附时间为90分钟，Ho&McKay模型预测的平衡容量qe为13.1406 mg·g-1，而实际结果为13.1398 mg·g-1。对于锌的吸附，考虑相同的最大浓度和时间，拟二级模型预测的吸附量为12.6743 mg·g-1，而实际值为12.6714 mg·g-1。在所有分析浓度下，0.15 g吸附剂对铅的吸收量(最大27.23 mg·g-1)大于锌的吸收量(最大8.28 mg·g-1)。

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Journal of Applied Life Sciences and Environment

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