Surface-exposed Silver Nanoclusters Inside Molecular Metal Oxide Cavities

Overview

Journal Nat Chem

Specialty Chemistry

Date 2023 Jun 8

PMID 37291453

Authors

Kentaro Yonesato

Daiki Yanai

Seiji Yamazoe

Daisuke Yokogawa

Takashi Kikuchi

Kazuya Yamaguchi

Kosuke Suzuki

Affiliations

Soon will be listed here.

Abstract

The surfaces of metal nanoclusters, including their interface with metal oxides, exhibit a high reactivity that is attractive for practical purposes. This high reactivity, however, has also hindered the synthesis of structurally well-defined hybrids of metal nanoclusters and metal oxides with exposed surfaces and/or interfaces. Here we report the sequential synthesis of structurally well-defined {Ag} nanoclusters in the cavity of ring-shaped molecular metal oxides known as polyoxometalates. The {Ag} nanoclusters possess exposed silver surfaces yet are stabilized both in solution and the solid state by the surrounding ring-shaped polyoxometalate species. The clusters underwent a redox-induced structural transformation without undesirable agglomeration or decomposition. Furthermore, {Ag} nanoclusters showed high catalytic activity for the selective reduction of several organic functional groups using H under mild reaction conditions. We believe that these findings will serve for the discrete synthesis of surface-exposed metal nanoclusters stabilized by molecular metal oxides, which may in turn find applications in, for example, the fields of catalysis and energy conversion.

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