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W4294843145 abstract "Electrocatalysis is a key driver in promoting the paradigm shift from the current fossil-fuel-based hydrocarbon economy to a renewable-energy-driven hydrogen economy. The success of electrocatalysis hinges primarily on achieving high catalytic selectivity along with maximum activity and sustained longevity. Many electrochemical reactions proceed through multiple pathways, requiring highly selective catalysts.Atomically dispersed metal catalysts have emerged as a new frontier in heterogeneous catalysis. In addition to the widely perceived advantages of maximized active site utilization and substantially reduced metal content, they have shown different catalytic selectivities in some electrocatalytic reactions compared to the traditional nanoparticle (NP)-based catalysts. Although there have been significant advances in their synthesis, the highly energetic nature of a single atomic site has made the preparation of atomically dispersed metal catalysts rely on empiricism rather than rational design. Consequently, the structural comprehension of a single atomic site and the understanding of its unusual electrocatalytic selectivity remain largely elusive.In this Account, we describe our endeavors toward developing general synthetic approaches for atomically dispersed metal catalysts for the discovery of new selective and active electrocatalysts and to understand their catalytic nature. We introduce synthetic approaches to produce a wide range of nonprecious- and precious-metal-based atomically dispersed catalysts and control their coordination environments. Metallomacrocyclic-compound-driven top-down and metal salt/heteroatom layer-based bottom-up strategies, coupled with a SiO2-protective-layer-assisted method, have been developed that can effectively generate single atomic sites while mitigating the formation of metallic NPs. The low-temperature gas-phase ligand exchange method can reversibly tune the coordination structure of the atomically dispersed metal sites. We have used the prepared atomically dispersed metal catalysts as model systems to investigate their electrocatalytic reactivity for renewable energy conversion and commodity chemical production reactions, in which high selectivity is important. The reactions of our interest include the following: (i) the oxygen reduction reaction, where O2 is reduced to either H2O or H2O2 via the four-electron or two electron pathway, respectively; (ii) the CO2 reduction reaction, which should suppress the hydrogen evolution reaction; and (iii) the chlorine evolution reaction, which competes with the oxygen evolution reaction. The type of metal center to which the reactant is directly bound is found to be the most important in determining the selectivity, which originates from the dramatic changes in the binding energy of each metal center with the reactants. The coordination structure surrounding the metal center also has a significant effect on the selectivity; its control can modulate the oxidation state of the metal center, thereby altering the binding strength with the reactants.We envisage that future advances in the synthesis of atomically dispersed metal catalysts, combined with the growing power of computational, spectroscopic, and microscopic methods, will bring their synthesis to the level of rational design. Elaborately designed catalysts can overcome the current limits of catalytic selectivity, which will help establish the field of atomically dispersed metal catalysts as an important branch of catalysis." @default.
W4294843145 created "2022-09-07" @default.
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W4294843145 date "2022-09-06" @default.
W4294843145 modified "2023-10-15" @default.
W4294843145 title "Steering Catalytic Selectivity with Atomically Dispersed Metal Electrocatalysts for Renewable Energy Conversion and Commodity Chemical Production" @default.
W4294843145 cites W1970750014 @default.
W4294843145 cites W1971327997 @default.
W4294843145 cites W1979371521 @default.
W4294843145 cites W1992277893 @default.
W4294843145 cites W1993998340 @default.
W4294843145 cites W2007471212 @default.
W4294843145 cites W2026875185 @default.
W4294843145 cites W2032100925 @default.
W4294843145 cites W2063042699 @default.
W4294843145 cites W2108520993 @default.
W4294843145 cites W2156690876 @default.
W4294843145 cites W2167035995 @default.
W4294843145 cites W2274258295 @default.
W4294843145 cites W2275807117 @default.
W4294843145 cites W2319861996 @default.
W4294843145 cites W2332178437 @default.
W4294843145 cites W2524524179 @default.
W4294843145 cites W2536246483 @default.
W4294843145 cites W2565767854 @default.
W4294843145 cites W2573377826 @default.
W4294843145 cites W2591938877 @default.
W4294843145 cites W2782723324 @default.
W4294843145 cites W2786699057 @default.
W4294843145 cites W2792743508 @default.
W4294843145 cites W2795272585 @default.
W4294843145 cites W2803427589 @default.
W4294843145 cites W2806260854 @default.
W4294843145 cites W2807945784 @default.
W4294843145 cites W2890740922 @default.
W4294843145 cites W2895819610 @default.
W4294843145 cites W2898000458 @default.
W4294843145 cites W2901787622 @default.
W4294843145 cites W2951356883 @default.
W4294843145 cites W2965836923 @default.
W4294843145 cites W2979596031 @default.
W4294843145 cites W2987506717 @default.
W4294843145 cites W2997372452 @default.
W4294843145 cites W3002587575 @default.
W4294843145 cites W3003732256 @default.
W4294843145 cites W3003948617 @default.
W4294843145 cites W3014910550 @default.
W4294843145 cites W3023326413 @default.
W4294843145 cites W3048466804 @default.
W4294843145 cites W3048536584 @default.
W4294843145 cites W3082557818 @default.
W4294843145 cites W3086202156 @default.
W4294843145 cites W3088197335 @default.
W4294843145 cites W3127398599 @default.
W4294843145 cites W3164134960 @default.
W4294843145 cites W3172717991 @default.
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W4294843145 cites W3201134638 @default.
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W4294843145 cites W4210378747 @default.
W4294843145 cites W4220782983 @default.
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W4294843145 doi "https://doi.org/10.1021/acs.accounts.2c00409" @default.
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