Preparation of Ti-doped BiOCl nanosheets and its piezoelectric photocatalytic performance

doi:10.19965/j.cnki.iwt.2022-0614

Abstract

Abstract:

The Ti doped BiOCl nanosheets were prepared by a one-step hydrothermal method. XRD，SEM，PFM and other analytical techniques were used to characterize the crystal structure and morphology of the prepared sample. With tetracycline（TC） as the target pollutant，the piezoelectric photocatalytic performance of Ti-BiOCl was studied under simulated sunlight and ultrasound. The results showed that BiOCl nanosheets exhibited roselike sheet with a thickness of about 25-250 nm and had good crystal structure and high piezoelectric response ability. With the action of light（300 W） and ultrasonic（100 W，45 kHz），the removal rate of TC by Ti-BiOCl reached 94.67% within 20 min. The first-order reaction rate at the room temperature was 0.168 min^-1，which was significantly better than photocatalytic or piezoelectric catalytic processes alone.

Key words: Ti-BiOCl nanosheets, piezoelectric photocatalysis, tetracycline

摘要：

采用一步水热法制备了Ti掺杂的BiOCl纳米片，并利用XRD、SEM和PFM以及其他分析测试技术对所制备催化剂的晶体结构和形貌进行测试。以四环素（TC）为目标污染物，在模拟太阳光和超声作用下，研究了Ti-BiOCl的压电光催化性能。结果表明，Ti-BiOCl材料由厚度为25~250 nm的纳米片组成，具有良好的晶体结构和较高的压电响应能力。在光（300 W）和超声（45 kHz，100 W）协同作用下，Ti-BiOCl在20 min内可以去除94.79%的TC。室温下一级反应速率常数达0.168 min^-1，显著优于单独光催化或单独压电催化过程。

关键词: Ti-BiOCl纳米片, 压电光催化, 四环素

CLC Number:

X703.1

Lihua LIU, Shan ZHONG, Lishan ZHANG, Baojiang LIU. Preparation of Ti-doped BiOCl nanosheets and its piezoelectric photocatalytic performance[J]. Industrial Water Treatment, 2023, 43(5): 101-106.

刘丽华, 钟山, 张漓杉, 刘保江. Ti掺杂BiOCl纳米片的制备及其压电光催化性能研究[J]. 工业水处理, 2023, 43(5): 101-106.

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URL: https://www.iwt.cn/EN/10.19965/j.cnki.iwt.2022-0614

https://www.iwt.cn/EN/Y2023/V43/I5/101

Figures/Tables 9

Fig. 1 XRD and UV-vis of Ti-BiOCl

Fig. 2 SEM and TEM of Ti-BiOCl

（a） SEM

（b） TEM

Fig.3 PFM of Ti-BiOCl

Fig. 4 TC degradation under different ultrasonic power and ultrasonic frequency

Fig. 5 TC degradation with different catalyst dosage

Fig. 6 Degradation of TC by Ti-BiOCl under different conditions（a） and the corresponding first order reaction rate constant（b）

Fig. 7 Effect of cycle times on degradation of TC

Fig. 8 ESR spectra for ·OH and ·O₂^-

Fig. 9 Piezoelectric photocatalytic degradation mechanism diagram of Ti-BiOCl

References 16

1	陈睿，汪恂，朱雷，等. g-C₃N₄/TiO₂复合材料的制备及降解四环素的研究［J］. 环境科学与技术，2022，45（1）：23-27.
	CHEN Rui， WANG Xun， ZHU Lei，et al. Preparation of g-C₃N₄/TiO₂ composite materials and degradation of tetracycline［J］. Environmental Science ＆ Technology，2022，45（1）：23-27.
2	安明泽，薛斌，杨照，等. TiO₂/生物炭复合材料光催化降解四环素与光解水制氢［J］. 广东化工，2022，49（8）：4-9. doi:10.3969/j.issn.1007-1865.2022.08.003
	AN Mingze， XUE Bin， YANG Zhao，et al. Photocatalytic degradation of tetracycline and photolysis of water for hydrogen production by TiO₂/biochar composite［J］. Guangdong Chemical Industry，2022，49（8）：4-9. doi:10.3969/j.issn.1007-1865.2022.08.003
3	刘行浩，朱文秀，张凤琳，等. 气液相等离子体对水中四环素去除及机制研究［J］. 工业水处理，2022，42（2）：75-80. URL
	LIU Xinghao， ZHU Wenxiu， ZHANG Fenglin，et al. Study on removal of tetracycline in water by gas-liquid plasma and its mechanism［J］. Industrial Water Treatment，2022，42（2）：75-80. URL
4	马瑞霄，周浩，张燕辉. RGO-ZnO光催化降解抗生素及还原Cr（Ⅵ）的研究［J］. 工业水处理，2021，41（3）：53-56. doi:10.11894/iwt.2020-0427
	MA Ruixiao， ZHOU Hao， ZHANG Yanhui. RGO-ZnO photocatalytic antibiotics degradation and Cr（Ⅵ） reduction［J］. Industrial Water Treatment，2021，41（3）：53-56. doi:10.11894/iwt.2020-0427
5	蔡博华，邹伟，朱雪梅，等. PVA/SiO₂@BiOBr纳米纤维的制备及其光催化性能［J］. 工业水处理，2022，42（6）：140-145. doi:10.19965/j.cnki.iwt.2021-0923
	CAI Bohua， ZOU Wei， ZHU Xuemei，et al. Fabrication of PVA/SiO₂@BiOBr nanofibers and their photocatalytic characteristics［J］. Industrial Water Treatment，2022，42（6）：140-145. doi:10.19965/j.cnki.iwt.2021-0923
6	董文静，任海深，谢天翼，等. 源于铋玻璃的富氧空位BiOCl光催化材料的原位合成及性能［J］. 无机化学学报，2022，38（3）：501-509. doi:10.11862/CJIC.2022.047
	DONG Wenjing， REN Haishen， XIE Tianyi，et al. In-situ synthesis and performance of oxygen vacancy-rich BiOCl photocatalytic material derived from bismuth-based glass［J］. Chinese Journal of Inorganic Chemistry，2022，38（3）：501-509. doi:10.11862/CJIC.2022.047
7	牛凤兴，蒋帅，高晓明，等. BiOCl/ZnO复合光催化剂的制备及其光催化性能［J］. 功能材料，2021，52（6）：6190-6194. doi:10.3969/j.issn.1001-9731.2021.06.028
	NIU Fengxing， JIANG Shuai， GAO Xiaoming，et al. Preparation of BiOCl/ZnO composite photocatalyst and its photocatalytic performance［J］. Journal of Functional Materials，2021，52（6）：6190-6194. doi:10.3969/j.issn.1001-9731.2021.06.028
8	常亮亮，韩靖靖，韩姿怡. BiOBr微球对诺氟沙星的压电-光催化降解性能研究［J］. 商洛学院学报，2021，35（4）：29-32.
	CHANG Liangliang， HAN Jingjing， HAN Ziyi. A study on piezoelectric-photocatalysis degyadation performanle of BiOBr microspheres on norfloxacin［J］. Journal of Shangluo University，2021，35（4）：29-32.
9	WANG Zhonglin. Piezopotential gated nanowire devices：Piezotronics and piezo-phototronics［J］. Nano Today，2010，5（6）：540-552. doi:10.1016/j.nantod.2010.10.008
10	ISMAIL M， WU Zheng， ZHANG Luohong，et al. High-efficient synergy of piezocatalysis and photocatalysis in bismuth oxychloride nanomaterial for dye decomposition［J］. Chemosphere，2019，228：212-218. doi:10.1016/j.chemosphere.2019.04.121
11	王晶，孟帅，张瀚洋，等. 络合剂对Ti掺杂BiFeO₃光催化材料的影响［J］. 产业与科技论坛，2022，21（8）：47-48. doi:10.3969/j.issn.1673-5641.2022.08.020
	WANG Jing， MENG Shuai， ZHANG Hanyang，et al. Effects of complexing agents on Ti-doped BiFeO₃ photocatalytic materials［J］. Industrial ＆ Science Tribune，2022，21（8）：47-48. doi:10.3969/j.issn.1673-5641.2022.08.020
12	WANG Donge， JIANG Hongfu， ZONG Xu，et al. Crystal facet dependence of water oxidation on BiVO₄ sheets under visible light irradiation［J］. Chemistry-A European Journal，2011，17（4）：1275-1282. doi:10.1002/chem.201001636
13	MOKHTARI F， TAHMASEBI N. Hydrothermal synthesis of W-doped BiOCl nanoplates for photocatalytic degradation of rhodamine B under visible light［J］. Journal of Physics and Chemistry of Solids，2021，149：109804. doi:10.1016/j.jpcs.2020.109804
14	ZHOU Xuefan， SUN Qiwei， ZHAI Di，et al. Excellent catalytic performance of molten-salt-synthesized Bi_0.5Na_0.5TiO₃ nanorods by the piezo-phototronic coupling effect［J］. Nano Energy，2021，84：105936. doi:10.1016/j.nanoen.2021.105936
15	ASHOKKUMAR M. The characterization of acoustic cavitation bubbles-An overview［J］. Ultrasonics Sonochemistry，2011，18（4）：864-872. doi:10.1016/j.ultsonch.2010.11.016
16	赵福友，金泽睿，曹帅杰，等. 超声协同g-C₃N₄光催化降解罗丹明B的研究［J］. 工业水处理，2021，41（1）：113-117. URL
	ZHAO Fuyou， JIN Zerui， CAO Shuaijie，et al. Degradation rhodamine B by ultrasond coupled with g-C₃N₄ photocatalysis［J］. Industrial Water Treatment，2021，41（1）：113-117. URL

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