Bimetallic Pt‐Hg Aerogels for Electrocatalytic Upgrading of Ethanol to Acetate

Abstract: Electrochemical upgrading of ethanol to acetic acid provides a promising strategy to couple with the current hydrogen production from water electrolysis. This work reports the design of a series of bimetallic PtHg aerogels, where the PtHg aerogel exhibits a 10.5‐times higher mass activity than that of commercial Pt/C toward ethanol oxidation. More impressively, the PtHg aerogel demonstrates nearly 100% selectivity toward the production of acetic acid. The operando infrared spectroscopic studies and nuclear ma… Show more

“…Metal–metal (alloy) interfaces have attracted significant attention in the field of electrocatalysis due to their prominent characteristics in terms of charge distribution, atomic arrangement, and stability. 99 Yu et al developed Ru/oxygen-doped-Ru core/shell nanoclusters, denoted as Ru–ST–X (X = 0.6%, 5%, and 12%), for eNO 3 RR to produce NH 3 , 100 and this work extensively exploits the strain effect generated at the interface to modulate the catalyst's performance. The variation in strain was achieved by manipulating the subsurface oxygen concentration (Fig.…”

Engineering interfacial architectures toward nitrate electrocatalysis and nitrogen neutral cycle

“…Metal–metal (alloy) interfaces have attracted significant attention in the field of electrocatalysis due to their prominent characteristics in terms of charge distribution, atomic arrangement, and stability. 99 Yu et al developed Ru/oxygen-doped-Ru core/shell nanoclusters, denoted as Ru–ST–X (X = 0.6%, 5%, and 12%), for eNO 3 RR to produce NH 3 , 100 and this work extensively exploits the strain effect generated at the interface to modulate the catalyst's performance. The variation in strain was achieved by manipulating the subsurface oxygen concentration (Fig.…”

Engineering interfacial architectures toward nitrate electrocatalysis and nitrogen neutral cycle

“…In this path, the ethanol molecules are oxidized to products such as acetaldehyde or acetic acid through a 4 electron or 2 electron transfer process. 19,20 The products of the C2 pathway have higher economic value than those of the C1 pathway. Designing electrocatalysts that can selectively oxidize ethanol into value-added products while minimizing carbon dioxide greenhouse gas has economic and environmental potential.…”

Amorphous cobalt–nickel borides boost electrocatalytic ethanol oxidation coupled with energy-saving hydrogen production

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