Mengzhen Song scite author profile

Fe-based MOFs (Fe-MOFs) are deemed promising Fenton-like catalysts due to their well-developed pores and accessible active sites. However, their inferior catalytic activity, iron leaching, and low H2O2 utilization always hinder their application as Fe-based MOF catalysts. In this work, we manipulated the structure of Fe-oxo nodes in MIL-88B(Fe) via a CuI species substitution method, affording a mixed-valence (Cu-incorporated Fe-MOFs) with highly improved Fenton-like performance. It is found that the CuI serves as a shuttle to promote transfer between FeII/FeIII, inducing the formation of a larger amount of stable FeII sites, which was proven by experimental and DFT calculation results. A linear relationship was observed for the Fenton-like performance and the amount of CuI species for the catalysts. The corresponding value of the •OH formation is 2.17 eV for Cu-incorporated MIL-88B(Fe), which is significantly lower than that of MIL-88B(Fe) (2.69 eV). Meanwhile, the enriched CuI species suppress Fe species leaching during the catalytic reaction. The Fe-ion leakage of 0.4Cu@MIL-88B is very tiny (0.01–0.03 mg/L), significantly less than that of MIL-88B (2.00–3.02 mg/L). At the same time, H2O2 utilization for 0.4Cu@ MIL-88B(Fe) is 88%, which is almost 4.4 times that of pure MIL-88B(Fe). This work provides insights into the rational design of Fe-MOFs as promising Fenton-like catalysts for wastewater treatment.

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The Stress and Morphology Evolution of CZO Films Under Different Growth Temperature

Zhao

Liu

et al. 2018

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Mengzhen Song

Visible light-driven H₂O₂ synthesis over Au/C₃N₄: medium-sized Au nanoparticles exhibiting suitable built-in electric fields and inhibiting reverse H₂O₂ decomposition

Perylene diimides coated Fe-MOFs as acid-tolerant photo-Fenton catalyst for phenol removal

Interface engineering of Ti-MOFs: Adsorption of anionic, cationic and neutral dyes in wastewater

Effects and Mechanisms of Cu Species in Fe-MOFs on Fenton-Like Catalytic Activity and Stability

The Stress and Morphology Evolution of CZO Films Under Different Growth Temperature

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Mengzhen Song

Visible light-driven H2O2 synthesis over Au/C3N4: medium-sized Au nanoparticles exhibiting suitable built-in electric fields and inhibiting reverse H2O2 decomposition

Perylene diimides coated Fe-MOFs as acid-tolerant photo-Fenton catalyst for phenol removal

Interface engineering of Ti-MOFs: Adsorption of anionic, cationic and neutral dyes in wastewater

Effects and Mechanisms of Cu Species in Fe-MOFs on Fenton-Like Catalytic Activity and Stability

The Stress and Morphology Evolution of CZO Films Under Different Growth Temperature

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Visible light-driven H₂O₂ synthesis over Au/C₃N₄: medium-sized Au nanoparticles exhibiting suitable built-in electric fields and inhibiting reverse H₂O₂ decomposition