FeCl3改性沸石制备条件优化及磷吸附机制研究

doi:10.14088/j.cnki.issn0439-8114.2023.12.013

湖北农业科学 ›› 2023, Vol. 62 ›› Issue (12): 63-68.doi: 10.14088/j.cnki.issn0439-8114.2023.12.013

FeCl₃改性沸石制备条件优化及磷吸附机制研究

郑新燕, 赵丹, 王木兰, 陈朝琼

成都医学院公共卫生学院,成都 610500

收稿日期:2022-10-11 发布日期:2024-01-10
通讯作者: 陈朝琼（1979-）,女,四川宜宾人,博士,主要从事环境有害物质监测处理研究,（电话）18180559760（电子信箱）13057890@qq.com。
作者简介:郑新燕（1999-）,女,四川眉山人,在读本科生,研究方向为卫生检验,（电话）18728392672（电子信箱）1585268986@qq.com。
基金资助:
四川省省级大学生创新创业训练计划项目（S202013705060）; 四川省科技厅重点研发项目（2018SZ0342; 2022YFS0498）

Optimizing the preparation conditions of FeCl₃ modified zeolite and investigating the phosphorus adsorption mechanism of the modified zeolite

ZHENG Xin-yan, ZHAO Dan, WANG Mu-lan, CHEN Zhao-qiong

School of Public Health, Chengdu Medical College, Chengdu 610500,China

Received:2022-10-11 Published:2024-01-10

摘要/Abstract

摘要： 为建立沸石FeCl₃改性条件的优化方法,提高磷吸附效率,阐明磷吸附机制,采用响应面法考察FeCl₃浓度、改性时间、改性转速、改性温度4因素对改性沸石磷吸附效果的影响,建立多元回归模型,确定改性条件的最优组合;用SEM、BET、XRD、FTIR表征技术,结合等温吸附、吸附动力学模型,阐明FeCl₃改性沸石的磷吸附机制。结果表明,4个因素对FeCl₃改性沸石的磷吸附效果有显著影响,改性条件与磷吸附率间的多元回归模型R²_（TP%）为0.987 9,R_adj²_（TP%）为0.975 9,拟合度好,响应面优化后最佳改性条件为FeCl₃浓度3.8 mol/L,改性时间6 h,改性温度32 ℃,改性转速186 r/min。表征结果表明,FeCl₃改性没有破坏沸石的骨架结构,Fe₂O₃负载于沸石表面,增加了比表面积,与磷的络合吸附作用可以提高磷吸附效率。Langmuir、Freundlich方程的R²分别为0.995 95、0.985 66,说明单层吸附与多层吸附同时存在。二级动力学模型的R²为0.870 09,大于一级动力学模型的R²（0.501 53）,说明二级动力学模型可以更好地描述FeCl₃改性沸石对磷酸盐的吸附动力学特征,FeCl₃改性沸石对磷酸盐的吸附以化学吸附为主。

关键词: FeCl₃改性沸石, 制备条件, 优化, 磷, 响应面法, 吸附机制

Abstract: In order to establish the optimization method of zeolite FeCl₃ modification conditions, improve the phosphorus adsorption efficiency, and elucidate the phosphorus adsorption mechanism, the response surface method was used to investigate the effects of four factors, namely, FeCl₃ concentration, modification time, modification rotational speed, and modification temperature on the phosphorus adsorption effect of modified zeolite, and to establish the multiple regression model to determine the optimal combinations of the modification conditions. The characterization techniques of SEM, BET, XRD, and FTIR combined with isothermal adsorption and adsorption kinetic modeling, were used to elucidate the phosphorus adsorption mechanism of FeCl₃-modified zeolite. The results showed that four factors had significant effects on the phosphorus adsorption of FeCl₃-modified zeolite, and the multiple regression model between the modification conditions and the phosphorus adsorption rate was 0.987 9 for R²_（TP%） and 0.975 9 for R_adj²_（TP%）, which was a good fit, and the optimal modification conditions after the response surface optimization were the FeCl₃ concentration of 3.8 mol/L, the modification time of 6 h, the modification temperature of 32 ℃, and the modification speed of 186 r/min. The characterization results showed that the FeCl₃ modification did not destroy the skeleton structure of zeolite, and the Fe₂O₃ loading on the surface of zeolite increased the specific surface area, and the complex adsorption with phosphorus could improve the adsorption efficiency of phosphorus. The R² of the Langmuir and Freundlich equations were 0.995 95 and 0.985 66, respectively, which indicated that both the monolayer and the multilayer adsorption existed at the same time. The R² of the second-stage kinetic model was 0.870 09, which was larger than that of the first-stage kinetic model （0.501 53）, indicating that the second-stage kinetic model could better characterize the adsorption kinetics of FeCl₃-modified zeolite on phosphate, and that the adsorption of phosphate by FeCl₃-modified zeolite was dominated by chemisorption.

Key words: FeCl₃-modified zeolite, preparation conditions, optimization, phosphorus, response surface method, adsorption mechanism

中图分类号:

X703.1

郑新燕, 赵丹, 王木兰, 陈朝琼. FeCl₃改性沸石制备条件优化及磷吸附机制研究[J]. 湖北农业科学, 2023, 62(12): 63-68.

ZHENG Xin-yan, ZHAO Dan, WANG Mu-lan, CHEN Zhao-qiong. Optimizing the preparation conditions of FeCl₃ modified zeolite and investigating the phosphorus adsorption mechanism of the modified zeolite[J]. HUBEI AGRICULTURAL SCIENCES, 2023, 62(12): 63-68.

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FeCl₃改性沸石制备条件优化及磷吸附机制研究

Optimizing the preparation conditions of FeCl₃ modified zeolite and investigating the phosphorus adsorption mechanism of the modified zeolite

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