巯基功能化大孔二氧化硅的制备及其对土壤中二乙三胺五乙酸（DTPA）提取态Cd、Pb的钝化性能

曹朋乐; 牛刘敏; 廉铭铭; 邱坤艳; 李亚轲; 李小红; 张治军

doi:10.7524/j.issn.0254-6108.2020071403

巯基功能化大孔二氧化硅的制备及其对土壤中二乙三胺五乙酸（DTPA）提取态Cd、Pb的钝化性能

1.
纳米杂化材料应用技术国家地方联合工程研究中心, 河南大学, 开封, 475004
2.
河南省土壤重金属污染监测与修复重点实验室, 济源, 459000
3.
河南河大纳米材料工程研究中心有限公司, 济源, 459000

通讯作者: Tel：15137808216，E-mail：xiaohongli@vip.henu.edu.cn;

基金项目:
国家重点研发计划（2019YFC1803602），河南省自然科学基金（202300410088），济源市重大科技专项(19012004)和河南大学一流学科培养项目(2020YLZDCG01)资助

Preparation of thiol groups modified macroporous structured nano-silica and its immobilization of Cd and Pb in contaminated soils

1.
National & Local Joint Engineering Research Center for Applied Technology of Hybrid Nanomaterials, Henan University, Kaifeng, 475004, China
2.
Key Laboratory for Monitoring and Remediation of Heavy Metal Polluted Soils of Henan Province, Jiyuan, 459000, China
3.
Engineering Research Center for Nanomaterials co. LTD, Jiyuan, 459000, China

Corresponding author: LI Xiaohong, xiaohongli@vip.henu.edu.cn ;

Fund Project: the Ministry of Science and Technology of China National Key Research and Development Program (2019YFC1803602), the Natural Science Foundation of the Henan Province（202300410088）, the Science and Technology Project of Jiyuan City（19012004）and the Subject Cultivation Project of Henan University（2020YLZDCG01）

摘要: 以硅酸钠为前驱体，分别制备表面带有氨基和环氧基团的纳米二氧化硅，利用氨基和环氧基团的桥接反应构建具有大孔结构的纳米二氧化硅，进一步在其表面负载具有重金属反应性的巯基基团，最终得到一种具有重金属高效反应性的纳米材料，并将其用于对土壤重金属的钝化修复．红外光谱、透射电镜、比表面积等分析显示，氨基和环氧基有机基团的修饰降低了纳米二氧化硅颗粒之间的团聚，两种基团之间的架桥反应，构建了具有较大孔径的二氧化硅聚集结构．通过研究改性二氧化硅对污染土壤中DTPA提取态Cd、Pb的钝化作用，发现巯基修饰的大孔径纳米二氧化硅（SiO₂-AE/SH）大幅提高了对重金属的钝化率；在添加比例为4%，修饰剂量为1.10 mmol·g⁻¹时，SiO₂-AE/SH对Cd的钝化效率是巯基修饰纳米二氧化硅（SiO₂-SH）的1.28倍，对Pb的钝化效率是SiO₂-SH的3.31倍．此研究为构建高效、大孔结构重金属钝化材料提供了一种方法，此材料也有望发展成为多孔硅过滤介质，应用于重金属废水处理．
- 表面修饰 /
- 纳米二氧化硅 /
- 污染土壤 /
- 钝化 /
- 镉/铅
Abstract: Sodium silicate is used as the precursor to prepare nano-SiO₂ with amine and epoxy groups on the surface. Two kinds of SiO₂ are bridged through the reaction between amino and epoxy groups to build nano-SiO₂ with macroporous structure. Thiol groups with heavy metal reactivity were further loaded on its surface to afford a type of highly reactive SiO₂ nanomaterial for immobilization of heavy metals in soils. FTIR, TEM, and specific surface area analysis show that the modification of amino and epoxy organic groups reduces the agglomeration between nano-SiO₂ particles, and the bridging reaction between amino and epoxy groups help construct a macroporous aggregated SiO₂ structure. By studying the immobilization effect of modified SiO₂ on the effective states of Cd and Pb in contaminated soils, the thiol-modified macroporous nano-SiO₂ greatly can improve the immobilization rate of heavy metals. When the addition ratio is 4% and the modification dosage is 1.10 mmol·g⁻¹, the immobilization efficiency of SiO₂-AE/SH to cadmium ions and lead ions is 1.28 times and 3.31 times than that of SiO₂-SH, respectively. This research provides a method for constructing high-efficiency, large-pore structure nanomaterials for heavy metal passivation, and this material is also expected to play roles in the treatment of heavy metal wastewater as porous silicon filter.
- surface modification /
- nano-silica /
- contaminated soils /
- immobilization /
- cadmium/lead
图 1 改性纳米二氧化硅的制备流程图

Figure 1. Flow chart of the synthesis of modified nano-silica

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图 2 改性纳米二氧化硅的结构设计

Figure 2. Formation and structure analysis of modified nano-silica

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图 3 SiO₂ (a)、SiO₂-SH(b)、SiO₂-AE(c)和SiO₂-AE/SH (d)的透射电镜图

Figure 3. TEM images of (a) Neat SiO₂, (b) SiO₂-SH, (c) SiO₂-AE and (d) SiO₂-AE/SH

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图 4 SiO₂ (a)，SiO₂-SH(b)，SiO₂-AE(c)和SiO₂-AE/SH (d)的Zeta电位值

Figure 4. Zeta potential of Neat SiO₂, SiO₂-SH, SiO₂-AE and SiO₂-AE/SH

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图 5 SiO₂，SiO₂-SH和SiO₂-AE/SH的N₂吸脱附曲线(a)和孔容-孔径微分（log）分布曲线(b)

Figure 5. Nitrogen Adsorption-Desorption isotherm (a) and Distribution curves of pore diameter (b) of Neat SiO₂, SiO₂-SH and SiO₂-AE/SH

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图 6 SiO₂(a)，SiO₂-AE(b)和SiO₂-AE/SH(c)的红外光谱

Figure 6. FT-IR spectra of (a) Neat SiO₂, (b) SiO₂-AE and (c) SiO₂-AE/SH．

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图 7 SiO₂，SiO₂-AE，SiO₂-SH和SiO₂-AE/SH对土壤中重金属Cd、Pb的钝化率

Figure 7. Immobilization rate of Neat SiO₂, SiO₂-AE, SiO₂-SH and SiO₂-AE/SH to heavy metals Cd and Pb in contaminated soils

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图 8 SiO₂和SiO₂-AE/SH对土壤中重金属Cd(a)、Pb(b)的钝化率

Figure 8. Immobilization rate of SiO₂-SH and SiO₂-AE/SH to heavy metals (a) Cd and (b) Pb in contaminated soils

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表 1 改性纳米二氧化硅的表面性质

Table 1. Surface properties of modified nano-silica

改性二氧化硅Modified nano-silica 比表面积S_BET/(m²·g⁻¹）平均孔径D_average/nm

SiO₂ 690.8 3.3
SiO₂−SH 562.5 6.8
SiO₂−AE/SH 376.9 10.6

改性二氧化硅Modified nano-silica 比表面积S_BET/(m²·g⁻¹）平均孔径D_average/nm

SiO₂ 690.8 3.3
SiO₂−SH 562.5 6.8
SiO₂−AE/SH 376.9 10.6

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随着工业化进程的推进，土壤重金属污染问题日益严重，对粮食生产安全、农业发展可持续性、土壤生态环境构成了严重威胁^[1-2]. 镉、铅作为最常见的土壤重金属污染物，因具有生物毒性大，污染强度高的特点而备受研究者关注^[3-4]. 重金属在土壤中隐蔽性强、不能被微生物降解，并可通过地下水、植物等媒介危及人类健康，因此采取措施对重金属污染土壤进行修复显得尤为必要. 对土壤重金属的化学钝化修复是指向土壤中加入钝化剂，以物理吸附、离子交换、氧化还原或与重金属形成络合物、螯合物、沉淀等作用方式使重金属转变为在土壤中不易溶出的形态，降低污染物的生物毒性和迁移性，从而达到安全修复污染土壤的目的^[5-7]. 该法具有操作简便、修复迅速、投入小、效果好、不改变土壤条件等优点，在重金属污染土壤修复中有着较为广阔的应用前景^[8].

传统的钝化材料主要有石灰类物质^[9]、有机物料^[10]、黏土矿物等^[11]，能够降低土壤溶液中的重金属离子的活性，但存在钝化效率低、对土壤扰动大等不足. 近些年来，纳米材料因具有大的比表面积、高的反应活性、强的吸附和螯合性能^[12]，已成为目前污染土壤修复研究的热点^[13]. 有研究者将纳米羟基磷灰石、纳米二氧化钛、纳米黑炭等^[14-16]应用于土壤污染治理，相关材料表现出极高的重金属钝化效率，但由于材料本身价格昂贵、稳定性差等缺点，限制了其在土壤修复中的应用. 因此，开发出一种钝化性能良好、经济环保的新型钝化材料具有极其重要的理论和现实意义.

纳米二氧化硅材料可以缓解土壤中重金属对植物的毒害，降低重金属的移动性^[17-18]，且成本低廉、无毒无污染，是极具应用潜力的钝化材料之一. 然而二氧化硅钝化重金属产物结合力较弱，在长期土壤环境中存在解吸的风险. 为了提高二氧化硅材料对重金属的吸附效率和结合力，人们用巯基、氨基硅烷偶联剂^[19-20]等对其表面进行修饰，可以明显提升材料对重金属Cd、Pb的钝化效果. 但是二氧化硅粒径小、表面能高，极易发生微粒间的团聚，降低了可与重金属发生反应的有机修饰剂的利用率. 改善纳米微粒的聚集状态，构建多孔、大孔结构的纳米二氧化硅材料可以充分发挥表面钝化基团的作用，提升其对土壤污染物的钝化性能.

本文以硅酸钠为二氧化硅前驱体，分别制备表面带有氨基和环氧基团的纳米二氧化硅，同时采用含巯基的硅烷偶联剂对其表面修饰，通过氨基和环氧基的架桥作用来支撑纳米二氧化硅的部分二次堆积孔结构，阻止由于二氧化硅表面羟基发生缩聚而造成的颗粒团聚，研究了二次堆积孔结构对有效基团巯基与重金属结合效率的影响.

3. 结论（Conclusion）

本文通过氨基/环氧基的架桥作用制备了一种孔结构丰富的纳米二氧化硅，在其表面进一步修饰巯基得到一种高效的重金属污染土壤纳米修复剂. 结果表明，有机碳链的支撑作用降低了二氧化硅粒子之间的团聚，使得所制备的纳米二氧化硅具有较大的二次堆积孔结构，提高了功能性基团巯基的利用率. 在添加比例为4%、巯基修饰量为1.71 mmol·g⁻¹时，所制备的大孔结构纳米二氧化硅修复剂可使土壤中DTPA提取态Cd、Pb的含量分别由12.58 mg·kg⁻¹和1335.00 mg·kg⁻¹降低至0.01 mg·kg⁻¹和55.94 mg·kg⁻¹，钝化效率分别达到99.9%和95.8%.

参考文献 (24)

巯基功能化大孔二氧化硅的制备及其对土壤中二乙三胺五乙酸（DTPA）提取态Cd、Pb的钝化性能

通讯作者: Tel：15137808216，E-mail：xiaohongli@vip.henu.edu.cn;

Preparation of thiol groups modified macroporous structured nano-silica and its immobilization of Cd and Pb in contaminated soils

Corresponding author: LI Xiaohong, xiaohongli@vip.henu.edu.cn ;

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巯基功能化大孔二氧化硅的制备及其对土壤中二乙三胺五乙酸（DTPA）提取态Cd、Pb的钝化性能

通讯作者: Tel：15137808216，E-mail：xiaohongli@vip.henu.edu.cn;

English Abstract

Preparation of thiol groups modified macroporous structured nano-silica and its immobilization of Cd and Pb in contaminated soils

Corresponding author: LI Xiaohong, xiaohongli@vip.henu.edu.cn ;

全文HTML

1.1. 试剂与仪器

1.2. 实验过程

1.2.1. 改性纳米二氧化硅钝化材料的制备

1.2.2. 改性纳米二氧化硅材料的测试

1.2.3. 改性纳米二氧化硅材料的钝化性能

2.1. 改性纳米二氧化硅材料的结构表征

2.2. 改性纳米二氧化硅材料对土壤中DTPA提取态Cd、Pb的钝化作用

2.2.1. 不同修饰结构对纳米二氧化硅钝化性能的影响

2.2.2. 不同巯基含量对纳米二氧化硅钝化性能的影响

目录

改性二氧化硅Modified nano-silica	比表面积S_BET/(m²·g⁻¹）	平均孔径D_average/nm
SiO₂	690.8	3.3
SiO₂−SH	562.5	6.8
SiO₂−AE/SH	376.9	10.6

巯基功能化大孔二氧化硅的制备及其对土壤中二乙三胺五乙酸（DTPA）提取态Cd、Pb的钝化性能

通讯作者: Tel：15137808216，E-mail：xiaohongli@vip.henu.edu.cn;

Preparation of thiol groups modified macroporous structured nano-silica and its immobilization of Cd and Pb in contaminated soils

Corresponding author: LI Xiaohong, xiaohongli@vip.henu.edu.cn ;

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出版历程

巯基功能化大孔二氧化硅的制备及其对土壤中二乙三胺五乙酸（DTPA）提取态Cd、Pb的钝化性能

通讯作者: Tel：15137808216，E-mail：xiaohongli@vip.henu.edu.cn;

English Abstract

Preparation of thiol groups modified macroporous structured nano-silica and its immobilization of Cd and Pb in contaminated soils

Corresponding author: LI Xiaohong, xiaohongli@vip.henu.edu.cn ;

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1.1. 试剂与仪器

1.2. 实验过程

1.2.1. 改性纳米二氧化硅钝化材料的制备

1.2.2. 改性纳米二氧化硅材料的测试

1.2.3. 改性纳米二氧化硅材料的钝化性能

2.1. 改性纳米二氧化硅材料的结构表征

2.2. 改性纳米二氧化硅材料对土壤中DTPA提取态Cd、Pb的钝化作用

2.2.1. 不同修饰结构对纳米二氧化硅钝化性能的影响

2.2.2. 不同巯基含量对纳米二氧化硅钝化性能的影响

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