Importance of Size and Contact Structure of Gold Nanoparticles for the Genesis of Unique Catalytic Processes

Overview

Journal Chem Rev

Publisher American Chemical Society

Specialty Chemistry

Date 2019 Dec 11

PMID 31820953

Citations 73

Authors

Tamao Ishida

Toru Murayama

Ayako Taketoshi

Masatake Haruta

Affiliations

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Abstract

Since the discovery of catalysis by Au nanoparticles (NPs), unique catalytic features of Au have appeared that are greatly different from those of Pd and Pt. In this Review, we aimed to disclose how the unique catalytic abilities of Au are generated with respect to (a) the contact structures between Au and its supports and (b) the size of the Au particles. For CO oxidation, the catalytic activity of Au on reducible metal oxides (MO) is strongly correlated with the amount of oxygen vacancies of the MO surface, which play a key role in O activation. Single atoms, bilayers of Au, sub-nm clusters, clusters (1-2 nm), and NPs (2-5 nm) have been proposed as the active sizes of the Au species, which may depend on the type of support. For propylene epoxidation, the presence of isolated TiO units in SiO supports is important for the production of propylene oxide (PO). Au NPs facilitate the formation of Ti-OOH species, which leads to PO in the presence of H and O, whereas Au clusters facilitate propylene hydrogenation. However, Au clusters can produce PO by using only O and water, whereas Au NPs cannot. For alcohol oxidation, the reducibility of the MO supports greatly influences the catalytic activity of Au, and single Au atoms more effectively activate the lattice oxygen of CeO. The basic and acidic sites of the MO surface also play an important role in the deprotonation of alcohols and the activation of aldehydes, respectively. For selective hydrogenation, heterolytic dissociation of H takes place at the interface between Au and MO, and the basic sites of MO contribute to H activation. Recent research into the reaction mechanisms and the development of well-designed Au catalysts has provided new insights into the preparation of high-performance Au catalysts.

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