1. Selective degradation of ceftriaxone sodium by surface molecularly imprinted BiOCl/Bi3NbO7 heterojunction photocatalyst.
- Author
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Zhang, Huining, Xiao, Yankui, Peng, Yaoqing, Tian, Lihong, Wang, Yan, Tang, Yuling, Cao, Yang, Wei, Zhiqiang, Wu, Zhiguo, Zhu, Ying, and Guo, Qi
- Subjects
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CEFTRIAXONE , *HETEROJUNCTIONS , *MOLECULAR imprinting , *ELECTRON spin , *SODIUM , *PHOTODEGRADATION , *SOLAR cells - Abstract
• A surface molecularly imprinted Z-type heterojunction composite photocatalyst was synthesized. • Photocatalytic materials can specifically recognize ceftriaxone sodium in water and preferentially adsorb it for photocatalytic degradation. • The selectivity depends on the holes with specific recognition ability on the surface of molecularly imprinted photocatalyst. • Molecularly imprinted photocatalyst has high stability and excellent reusability. By using the surface molecular imprinting technique, BiOCl/Bi 3 NbO 7 was used as the substrate photocatalyst and ceftriaxone sodium (CTRX) was used as the template. A molecularly imprinted photocatalyst with specific recognition and photocatalytic synergy for CTRX was synthesized. Due to the excellent photoelectric properties and the successful formation of CTRX-imprinted cavities on the imprinted layer surface. The characterization results showed that MIP-3 has the advantages of uniform particle size and high separation efficiency of photogenerated carriers. The molecularly imprinted photocatalyst MIP-3 showed remarkable synergy and selectivity in both adsorption-photocatalysis of CTRX. Further experimental results showed that MIP-3 exhibited high selective adsorption performance for both high and low concentrations of CTRX in the 30 min static adsorption experiment. About 92 % of CTRX was degraded in the 100 min light experiment, which was a large improvement compared with BiOCl/Bi 3 NbO 7. The selectivity of MIP-BNO was evaluated by comparing the degradation efficiency of MIP-3 on CTRX and chloramphenicol (CIP). Compared to non-imprinted photocatalyst NIP-BNO, MIP-3 has a higher selectivity coefficient of 2.58 and a faster degradation kinetic rate of 0.0169 min−1. The stability experiments showed that MIP-3 has good recoverability and stability during photocatalytic degradation. The mechanism of selective photocatalytic degradation of CTRX by MIP-3 was investigated by UV–visible spectroscopy, radical capture experiments, and electron spin tests. The possible degradation pathway of CTRX was also analyzed by LC-MS. In conclusion, this study confirms that the combination of surface molecular imprinting and photocatalyst has great potential to provide a promising solution for the treatment of low-level, highly toxic target pollutants in mixed wastewater. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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