Boosting CO2 chemical fixation over MOF-808 by the introduction of functional groups and defective Zr sites

Minghui Zhou; Zhengyan Qu; Jiuxuan Zhang; Hong Jiang; Zhenchen Tang; Rizhi Chen

doi:10.1039/d3cc06154j

Boosting CO₂ chemical fixation over MOF-808 by the introduction of functional groups and defective Zr sites

Minghui Zhou, Zhengyan Qu, Jiuxuan Zhang, Hong Jiang, Zhenchen Tang, Rizhi Chen

COLLEGE OF CHEMICAL ENGINEERING

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

CO₂ cycloaddition has emerged as a promising approach for producing value-added cyclocarbonates and mitigating greenhouse gas emissions. Although MOF-808 serves as a stable catalyst for cycloaddition, its limited activity constrains broader applications. Through the modification with a fluoride group via a ligand exchange method, F-MOF-808-1.5 exhibits exceptional performance, achieving a 98.8% conversion with 97.8% selectivity to epichlorohydrin carbonate—marking a substantial 100% improvement compared to pristine MOF-808. The defective Zr sites and the electron-withdrawing groups synergistically promote the ring opening of epoxides. Furthermore, the catalyst demonstrates high stability over multiple reaction cycles. Notably, without adding solvents and co-catalysts, F-MOF-808-1.5 outperforms most reported MOF-based catalysts.

Original language	English
Pages (from-to)	3170-3173
Number of pages	4
Journal	Chemical Communications
Volume	60
Issue number	23
DOIs	https://doi.org/10.1039/d3cc06154j
State	Published - 19 Feb 2024

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abstract = "CO2 cycloaddition has emerged as a promising approach for producing value-added cyclocarbonates and mitigating greenhouse gas emissions. Although MOF-808 serves as a stable catalyst for cycloaddition, its limited activity constrains broader applications. Through the modification with a fluoride group via a ligand exchange method, F-MOF-808-1.5 exhibits exceptional performance, achieving a 98.8% conversion with 97.8% selectivity to epichlorohydrin carbonate—marking a substantial 100% improvement compared to pristine MOF-808. The defective Zr sites and the electron-withdrawing groups synergistically promote the ring opening of epoxides. Furthermore, the catalyst demonstrates high stability over multiple reaction cycles. Notably, without adding solvents and co-catalysts, F-MOF-808-1.5 outperforms most reported MOF-based catalysts.",

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AU - Zhou, Minghui

AU - Qu, Zhengyan

AU - Zhang, Jiuxuan

AU - Jiang, Hong

AU - Tang, Zhenchen

AU - Chen, Rizhi

PY - 2024/2/19

Y1 - 2024/2/19

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AB - CO2 cycloaddition has emerged as a promising approach for producing value-added cyclocarbonates and mitigating greenhouse gas emissions. Although MOF-808 serves as a stable catalyst for cycloaddition, its limited activity constrains broader applications. Through the modification with a fluoride group via a ligand exchange method, F-MOF-808-1.5 exhibits exceptional performance, achieving a 98.8% conversion with 97.8% selectivity to epichlorohydrin carbonate—marking a substantial 100% improvement compared to pristine MOF-808. The defective Zr sites and the electron-withdrawing groups synergistically promote the ring opening of epoxides. Furthermore, the catalyst demonstrates high stability over multiple reaction cycles. Notably, without adding solvents and co-catalysts, F-MOF-808-1.5 outperforms most reported MOF-based catalysts.

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Boosting CO₂ chemical fixation over MOF-808 by the introduction of functional groups and defective Zr sites

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