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Radiolytic Water Splitting Sensitized by Nanoscale Metal–Organic Frameworks

Changjiang Hu, Liwei Cheng, Li-Heng Zhou, Zhiwen Jiang, Pingping Gan, Shuiyan Cao, Qiuhao Li, Chong Chen, Yunlong Wang, Mehran Mostafavi, Shuao Wang, Jun Ma

2023Journal of the American Chemical Society37 citationsDOIOpen Access PDF

Abstract

High-energy radiation that is compatible with renewable energy sources enables direct H 2 production from water for fuels; however, the challenge is to convert it as efficiently as possible, and the existing strategies have limited success. Herein, we report the use of Zr/Hf-based nanoscale UiO-66 metal–organic frameworks as highly effective and stable radiation sensitizers for purified and natural water splitting under γ-ray irradiation. Scavenging and pulse radiolysis experiments with Monte Carlo simulations show that the combination of 3D arrays of ultrasmall metal-oxo clusters and high porosity affords unprecedented effective scattering between secondary electrons and confined water, generating increased precursors of solvated electrons and excited states of water, which are the main species responsible for H 2 production enhancement. The use of a small quantity (<80 mmol/L) of UiO-66-Hf-OH can achieve a γ-rays-to-hydrogen conversion efficiency exceeding 10% that significantly outperforms Zr-/Hf-oxide nanoparticles and the existing radiolytic H 2 promoters. Our work highlights the feasibility and merit of MOF-assisted radiolytic water splitting and promises a competitive method for creating a green H 2 economy.

Topics & Concepts

RadiolysisChemistryWater splittingHydrogenSolvated electronHydrogen productionOxideMetal-organic frameworkElectronExcited stateNanotechnologyCatalysisPhotocatalysisAtomic physicsPhysical chemistryMaterials scienceOrganic chemistryPhysicsAqueous solutionAdsorptionQuantum mechanicsMetal-Organic Frameworks: Synthesis and ApplicationsAdvanced Photocatalysis TechniquesRadioactive element chemistry and processing