纺织学报 ›› 2023, Vol. 44 ›› Issue (05): 155-163.doi: 10.13475/j.fzxb.20220503201

• 染整与化学品 • 上一篇    下一篇

可见光响应的介孔TiO2光降解罗丹明B机制及其降解途径

王国琴1,2, 付小航1, 朱羽科1, 吴礼光1, 王挺1,2(), 蒋孝佳1,2, 陈华丽1   

  1. 1.浙江工商大学 环境科学与工程学院, 浙江 杭州 310012
    2.浙江工商大学 分析测试中心, 浙江 杭州 310012
  • 收稿日期:2022-05-10 修回日期:2023-02-14 出版日期:2023-05-15 发布日期:2023-06-09
  • 通讯作者: 王挺(1980—),男,副研究员,博士。主要研究方向为功能材料和高级氧化技术。E-mail: zjwtwaiting@hotmail.com。
  • 作者简介:王国琴 (1984—),女,实验师,硕士。主要研究方向为高级氧化技术。
  • 基金资助:
    国家自然科学基金项目(21776250);浙江省自然科学基金项目(LY19B060004);浙江省自然科学基金项目(LY20B060001)

Photodegradation mechanism and pathway of visible light-response mesoporous TiO2 for Rhodamine B

WANG Guoqin1,2, FU Xiaohang1, ZHU Yuke1, WU Liguang1, WANG Ting1,2(), JIANG Xiaojia1,2, CHEN Huali1   

  1. 1. School of Environmental Science and Engineering, Zhejiang Gongshang University, Hangzhou, Zhejiang 310012, China
    2. Instrumental Analysis Center, Zhejiang Gongshang University, Hangzhou, Zhejiang 310012, China
  • Received:2022-05-10 Revised:2023-02-14 Published:2023-05-15 Online:2023-06-09

摘要:

为获得可见光响应的高效介孔TiO2光催化剂,利用软模板法制备了螺旋堆积的手性介孔TiO2。对比分析了手性介孔TiO2和非手性介孔TiO2的差异。通过自由基捕获实验和电子自旋共振 (ESR) 光谱,结合福井指数(f-)的计算探索了手性介孔TiO2降解罗丹明B(RhB)的机制和路径。结果表明,手性介孔TiO2的螺旋堆积结构引入了更多缺陷,从而其Ti3+和氧空穴的含量都高于非手性介孔TiO2,因此具有更强的可见光响应和降解活性,其对RhB的去除率超过非手性介孔TiO2的4倍;手性介孔TiO2降解有机污染物分子的主要活性物种是光生空穴h+;越容易给出电子的原子位点(即f-值越高)越容易受到h+的攻击发生降解;降解过程中中间产物分析进一步得到了可见光激发手性介孔TiO2降解RhB的主要路径。

关键词: 手性介孔二氧化钛, 可见光催化降解, 罗丹明B, 染料污染物, 降解路径, 废水处理

Abstract:

Objective In order to promote the practical application of deep treatment of organic pollutants in slightly polluted water bodies using heterogeneous photocatalysis, mesoporous TiO2 photocatalyst as a novel photocatalyst with a pore size of 2-50 nm has a particle size of larger than 200 nm, so it was very easy to recycle, thus avoiding the potential nano-toxicity of the nano photocatalyst.

Method In order to obtain a visible-light-responsive mesoporous TiO2 photocatalyst, chiral mesoporous TiO2 with spirally-stacked structure was prepared by a soft template method constructed with chiral surfactants. By means of various characterization methods such as X-ray spectroscopy, scanning electron microscopy, X-ray photoelectron spectroscopy, surface area and pore size analysis, and circular dichroism (CD), the differences in structure and visible light response of chiral mesoporous TiO2 and achiral mesoporous TiO2 were compared and analyzed. The photodegradation experiment for Rhodamine B (RhB) under visible light excitation was adopted to evaluate their catalytic performance, thus exploring the mechanism and pathway for degrading RhB by chiral mesoporous TiO2.

Results The average pore diameters of the two mesoporous TiO2 were 6.4 nm and 8.6 nm. The specific surface area, pore volume and pore size of chiral mesoporous TiO2 prepared by chiral surfactants were slightly smaller than those of achiral mesoporous TiO2. The particle size of the chiral mesoporous TiO2 particles was about 200 nm, and it presented an obvious helical packing structure, which also showed a significant chiral correspondence effect. On the other hand, the morphology of achiral mesoporous TiO2 did not show the structure of helical stacking, but only showed the aggregation structure of some particles. Both chiral mesoporous TiO2and achiral mesoporous TiO2had two mixed crystal forms of anatase and rutile (Fig.4). The helical stacking structure of chiral mesoporous TiO2 introduced more defects into the catalyst, so that the contents of Ti3+ and oxygen holes were higher than those of mesoporous TiO2 (Fig.5). Owing to its large specific surface area and excellent visible light response performance, chiral mesoporous TiO2 had a high degradation activity for RhB (the removal rate reached 78% within 5 h), and the degradation process conformed to first-order kinetics (Fig.6). The photocatalytic performance of achiral mesoporous TiO2 (the removal rate was only 16% within 5 h) was much lower than that of chiral mesoporous TiO2(Fig.6). Although the adsorption performance of the two catalysts for RhB was similar, the removal rate of RhB by chiral mesoporous TiO2 was more than 4 times that of achiral mesoporous TiO2(Fig.6). Radical trapping experiments and electron spin resonance (ESR) spectroscopy showed that the active species of chiral mesoporous TiO2 to degrade organic pollutant molecules under the excitation of visible light are ·O2-, ·OH and photogenerated h+ (Fig.7 and 8). When capturing ·O2-, ·OH and h+ during the photodegradation, the removal rates for RhB by the chiral mesoporous TiO2 decreased by 19.2%, 39.7% and 60.2%, respectively, compared with the photodegradation process without adding capture agent (Fig.7). It showed that ·O2-, ·OH and h+ all participated in the degradation of RhB as active species in the photodegradation process. And h+ was the main active species for degrading organic pollutants, followed by ·OH, and ·O2- was the least involved in the photodegradation (Fig.8). The calculation of the Fukui index (f-) of each atom in the RhB molecule proved that the atomic sites that were more likely to give electrons were easily attacked by photogenerated holes for degradation (Fig.9). By analyzing the intermediate products generated during the degradation process (Tab.2), the main pathway of the RhB degradation by chiral mesoporous TiO2 under irradiation of visible light was further obtained (Fig.10).

Conclusion From the results of our work, the degradation pathway of RhB pollutants was obtained. The first step was that h+ attacked on the C—N bond of the RhB molecules to remove the ethyl group. Then, multiple demethylation and deethylation reactions, and deamination processes were carried out. Until the vulnerable C—N bond site disappears, the h+ would attack the carboxyl group with high electron density and the benzene ring to enable the ring-opening reaction to be continued, and finally RhB was mineralized into CO2, H2O and other inorganic substances.

Key words: chiral mesoporous TiO2, visible light photodegradation, Rhodamine B, dye pollutant, degradation pathway, wastewater treatment

中图分类号: 

  • O647

图1

不同介孔TiO2的氮气吸附脱附等温线"

表1

不同介孔TiO2的比表面积、孔容和平均孔径"

催化剂 比表面积/
(m2·g-1)
孔容/
(cm3·g-1)
孔径/
nm
手性介孔TiO2 77.33 0.243 5 6.4
介孔TiO2 113.00 0.581 5 8.6

图2

不同介孔TiO2的SEM 照片"

图3

不同介孔TiO2的圆二色谱图"

图4

不同介孔TiO2的XRD衍射图"

图5

不同介孔TiO2的XPS图谱和光电流响应曲线"

图6

不同TiO2光催化剂对RhB的降解曲线图"

图7

捕获剂对手性介孔TiO2降解RhB的影响"

图8

可见光激发手性介孔TiO2过程的ESR图谱"

图9

RhB分子中原子分布图"

表2

RhB光降解1 h后反应体系的中间产物"

化合物编号 A B C D E F G H I
质荷比m/z 443 415 387 373 359 331 301 244 230

图10

可见光激发下手性介孔TiO2光降解RhB的路径"

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