1. Boosting photo-Fenton process enabled by ligand-to-cluster charge transfer excitations in iron-based metal organic framework.
- Author
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Li, Wen-Qiang, Wang, Yi-Xuan, Chen, Jia-Qi, Hou, Nan-Nan, Li, Yuan-Ming, Liu, Xiao-Cheng, Ding, Rong-Rong, Zhou, Guan-Nan, Li, Qi, Zhou, Xiao-Guo, and Mu, Yang
- Subjects
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METAL-organic frameworks , *CHARGE transfer , *HABER-Weiss reaction , *VISIBLE spectra , *IRON - Abstract
Iron-based metal organic frameworks (MOFs) are widely adopted to mediate heterogeneous photo-Fenton reaction, but poor charge separation efficiency in iron-oxo clusters of MOF usually results in the dull Fe(III)/Fe(II) transformation. In this study, ligand-to-cluster charge transfer (LCCT) excitations were first introduced to photo-Fenton process toward accelerating Fe(III)/Fe(II) transformation by constructing new iron-based MOF nanorods with porphyrin ligand (Fe-TCPP). Fe-TCPP with LCCT excitations showed a maximum kinetic constant of 0.23 min-1 for ciprofloxacin (CIP) degradation at neutral pH under visible light irradiation, which is remarkably better than most of the state-of-the-art photocatalysts. Experimental and theoretical analyses collaboratively verify that LCCT excitations within Fe-TCPP dramatically accelerate Fe(III)/Fe(II) transformation, which generate more ∙OH for quick CIP elimination. Additionally, this LCCT excitations strategy is also effective for the photo-Fenton-like system induced by copper-based MOFs. Our study presents a novel strategy to intensify MOFs based photo-Fenton/Fenton-like processes, upon which the high-efficiency contaminant removal is expected. [Display omitted] • LCCT excitations were first introduced to MOFs based photo-Fenton process. • Fe-TCPP with LCCT excitations displayed best antibiotic degradation performance. • LCCT excitations occurrence within Fe-TCPP was identified by different methods. • LCCT excitations within Fe-TCPP speed Fe(III)/Fe(II) transformation and ∙OH generation. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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