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Rational Design of a Quasi-Metal–Organic Framework by Ligand Engineering for Efficient Biomass Upgrading

Ning‐Yu Huang, Bingxian Chu, Di Chen, Bing Shao, Yu‐Tao Zheng, Lei Li, Xinke Xiao, Qiang Xü

2025Journal of the American Chemical Society66 citationsDOI

Abstract

The electrooxidation of 5-hydroxymethylfurfural (HMF) to 2,5-furandicarboxylic acid (FDCA), a monomer for degradable bioplastic, is a promising strategy for biomass upgrade and yet requires well-designed catalysts with high efficiency and selectivity. Taking advantage of the open metal sites of metal-organic frameworks (MOFs), quasi-MOFs represent viable catalysts, but the poor designability and unpredictable structures hinder their development. In this work, a Ni-based quasi-MOF was rationally designed and synthesized by controlled ligand engineering. Compared to the fully occupied metal clusters in the pristine MOFs, the accessible Ni sites in quasi-MOFs can efficiently convert HMF to FDCA with remarkable Faradaic efficiency (99.2%) and FDCA selectivity (98.3%). In situ characterizations and mechanistic analysis revealed that the open Ni sites created by partial ligand disconnection in quasi-MOFs are critical to the formation of high-valent active species and HMF oxidation. Moreover, serving as the anode in an integrated electrolysis system, such a quasi-MOF can not only reduce the cell voltage for hydrogen generation but also produce high-purity FDCA with good yield, offering a new opportunity for the simultaneous production of high value-added chemicals and sustainable hydrogen.

Topics & Concepts

ChemistryRational designBiomass (ecology)Ligand (biochemistry)MetalBiochemical engineeringCombinatorial chemistryOrganic chemistryEnvironmental chemistryNanotechnologyBiochemistryEcologyReceptorMaterials scienceEngineeringBiologyMetal-Organic Frameworks: Synthesis and ApplicationsCatalysis for Biomass ConversionCarbon dioxide utilization in catalysis