Bulk-to-Surface Proton-Coupled Electron Transfer Reactivity of the Metal-Organic Framework MIL-125

Overview

Journal J Am Chem Soc

Publisher American Chemical Society

Specialty Chemistry

Date 2018 Nov 6

PMID 30392350

Citations 10

Authors

Caroline T Saouma

Sarah Richard

Simon Smolders

Murielle F Delley

Rob Ameloot

Frederik Vermoortele

Dirk E De Vos

James M Mayer

Affiliations

Soon will be listed here.

Abstract

Stoichiometric proton-coupled electron transfer (PCET) reactions of the metal-organic framework (MOF) MIL-125, TiO(OH)(bdc) (bdc = terephthalate), are described. In the presence of UV light and 2-propanol, MIL-125 was photoreduced to a maximum of 2( e/H) per Ti node. This stoichiometry was shown by subsequent titration of the photoreduced material with the 2,4,6-tri- tert-butylphenoxyl radical. This reaction occurred by PCET to give the corresponding phenol and the original, oxidized MOF. The high level of charging, and the independence of charging amount with particle size of the MOF samples, shows that the MOF was photocharged throughout the bulk and not only at the surface. NMR studies showed that the product phenol is too large to fit in the pores, so the phenoxyl reaction must have occurred at the surface. Attempts to oxidize photoreduced MIL-125 with pure electron acceptors resulted in multiple products, underscoring the importance of removing e and H together. Our results require that the e and H stored within the MOF architecture must both be mobile to transfer to the surface for reaction. Analogous studies on the soluble cluster TiO(OOC Bu) support the notion that reduction occurs at the Ti MOF nodes and furthermore that this reduction occurs via e/H (H-atom) equivalents. The soluble cluster also suggests degradation pathways for the MOFs under extended irradiation. The methods described are a facile characterization technique to study redox-active materials and should be broadly applicable to, for example, porous materials like MOFs.

Citing Articles

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Electrochemically Determined and Structurally Justified Thermochemistry of H atom Transfer on Ti-Oxo Nodes of the Colloidal Metal-Organic Framework Ti-MIL-125.

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