Metal Organic Framework Derived Porous BiFeO 3 /PVDF Composites for Synergistic Piezo-Photocatalytic Degradation of Rhodamine B

材料科学 罗丹明B 聚偏氟乙烯 压电 光催化 复合数 多孔性 化学工程 降级(电信) 异质结 电场 复合材料 金属有机骨架 纳米颗粒 催化作用 环境污染 纳米发生器 分子 电极 压电响应力显微镜 密度泛函理论 分解水 多孔介质 半导体 纳米技术 罗丹明 纳米复合材料 化学稳定性 表面光电压
作者
Ziwei Wu,Xinpeng Chen,Jingqi Cao,Yi Wang,Yongxuan Xiang,Yixiao Li,Haoyu Wang,Hongmei Cao,Tieling Xing
出处
期刊:Langmuir [American Chemical Society]
卷期号:42 (8): 6376-6392
标识
DOI:10.1021/acs.langmuir.5c06253
摘要

Photocatalysis and piezocatalysis rely on light energy and mechanical energy (via the piezoelectric effect) as driving forces, respectively. Both have been successfully applied to pollutant degradation and wastewater treatment as advanced oxidation processes. However, in this study, BiFeO3 nanoparticles derived from MIL-101 were solidified in a flexible polyvinylidene fluoride (PVDF) porous structure, forming a dynamic synergistic effect between the piezoelectrically polarized electric field induced by mechanical agitation and the photogenerated carriers. Additionally, the hydrolytic inactivation of the material was inhibited by the chemical barrier effect of PVDF, while the charge separation at the heterojunction interface was directionally driven by the built-in electric field generated by the piezoelectric effect. The BiFeO3/PVDF composite membrane degraded 97.1% of RhB after 60 min of treatment under the synergistic effect of stirring and light. Free radical trapping and electron spin resonance (ESR) analysis confirmed that •O2– and •OH were the key active species (contributing over 60%). Piezoresponse Force Microscopy (PFM) test revealed the mechanism behind the enhancement of the built-in electric field, and density functional theory (DFT) calculations combined with Fukui’s function elucidated that the N4, N5, and C6 sites in the RhB molecule were the preferred targets for free radical attack. Plant growth experiments verified the environmental safety of the system. The BiFeO3/PVDF porous composites with piezoelectric photocatalytic properties proposed in this study provide a promising solution for developing novel materials for efficient catalysis of organic pollutants in water.
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