Litcius/Paper detail

Proton‐Coupling Electron Transfer Kinetics Modulation via Substitution Isomerism of Amino Groups in MOFs to Switch CO <sub>2</sub> Photoreduction Pathways from HCOOH to CH <sub>3</sub> COOH

Xia Li, Ren Ma, Zhengqiang Xia, Qibin Yang, Yi-Xia Ren, Gang Xie, Sanping Chen

2025Advanced Materials14 citationsDOI

Abstract

Abstract Selective photoreduction of CO 2 into high‐value C2 products is highly desirable but challenging due to the high‐energy‐barrier C‐C coupling and sluggish proton‐coupling electron transfers (PCET). Herein, CsPbBr 3 (CPB) quantum dots are in‐situ encapsulated within amino‐functionalized Fe/UiO‐67‐X (X = meta ‐NH 2 , ortho ‐NH 2 , ortho ‐2NH 2 ) frameworks for efficient CO 2 photoreduction. X‐ray absorption spectroscopy confirms the presence of charge‐asymmetrical ZrFe sites that promote C‐C coupling and the covalently‐connected Pb‐N electron‐transfer “bridge” that enhances carrier kinetics. Notably, the o ‐2NH 2 ‐functionalized CPB@Fe/UiO‐67‐ o ‐2NH 2 achieves a CH 3 COOH productivity of 257.22 µmol·g −1 ·h −1 with 98.72% selectivity, whereas the m ‐NH 2 ‐substituted analog (CPB@Fe/UiO‐67‐ m ‐NH 2 ) exclusively produces HCOOH. Comprehensive analyses demonstrate that the o ‐NH 2 groups facilitate ultrafast electron transfer via a near Pb–N bridge and organize interfacial H 2 O into proton‐conducting networks to ensure synchronized proton‐supply. In‐situ DRIFT and DFT calculations confirm that the o ‐NH 2 ‐induced rapid PCETdrives the conversion of * COOH at Zr sites to * CO, which subsequently couples with stabilized * COOH at Fe sites to form the critical * OC‐COOH with the lowest energy barrier compared to * HOOC‐COOH or * OC‐CO pathways. This work establishes a design paradigm that necessitates the “temporal alignment” and “spatial coupling” of H⁺ and e − at active sites for achieving high‐performance CO 2 ‐to‐C2 photoreduction by modulating interfacial electron‐proton dynamics through simple group isomerism.

Topics & Concepts

Electron transferMaterials scienceUltrafast laser spectroscopyCoupling (piping)PhotochemistryChemical physicsKineticsSpectroscopyAbsorption (acoustics)ElectronUltrashort pulseAbsorption spectroscopyElectron donorWork (physics)Electron transport chainFemtochemistryAcceptorModulation (music)Energy transferRotational–vibrational couplingFlash photolysisQuantum dotSubstitution (logic)Electron acceptorQuantumPhotoinduced electron transferMolecular dynamicsAdvanced Photocatalysis TechniquesCO2 Reduction Techniques and CatalystsPerovskite Materials and Applications
Proton‐Coupling Electron Transfer Kinetics Modulation via Substitution Isomerism of Amino Groups in MOFs to Switch CO <sub>2</sub> Photoreduction Pathways from HCOOH to CH <sub>3</sub> COOH | Litcius