Activation Effect of Electrochemical Cycling on Gold Nanoparticles towards the Hydrogen Evolution Reaction in Sulfuric Acid

Abstract: A B S T R A C TThis article reports a study of electrochemical cycling effects on hydrogen evolution catalytic activity of gold nanoparticles in sulfuric acid. We found that after cycling within the double layer regime, up to 0.64 V vs RHE, there is a dramatic effect on the HER activity of gold nanoparticles: 128 mV drop of the overpotential, a decrease of 23 mV/dec for the Tafel slope as well as a nearly twenty times increase of the turn-over frequency (TOF). This enhanced activity is tentatively assigned to … Show more

“…The reduction in the -η 100 at this electrode is 69% (with respect to the Cu/Ni/NiZn), which demonstrates that the presence of Au on the catalyst surface favours the hydrogen evolution kinetics and reduces the energy input for activating the HER [23,24]. However, the smallest Tafel slope appeared at the Au-modified electrode indicates a faster adsorption of H on the catalyst surface that leads to a faster HER rate [14,15]. Gold was Gold-supported activated NiZn coatings: HER and corrosion studies R. Solmaz reported to be a poor electrocatalyst for the HER because of the weak bond with H; namely, this metal is a poor substrate for hydrogen adsorption [12,24].…”

“…Gold was Gold-supported activated NiZn coatings: HER and corrosion studies R. Solmaz reported to be a poor electrocatalyst for the HER because of the weak bond with H; namely, this metal is a poor substrate for hydrogen adsorption [12,24]. However, the smallest Tafel slope appeared at the Au-modified electrode indicates a faster adsorption of H on the catalyst surface that leads to a faster HER rate [14,15]. Figure 2c shows the representative Nyquist plots of the working electrodes at À0.100-V overpotential.…”

“…In literature, there are only some studies on the hydrogen evolution activity of balk or nanostructured Au/or Au alloys [10][11][12][13][14][15][16][17]. Promising results could be obtained by the Au-nanoparticles or clusters [14][15][16][17] because more active centres are available on these surfaces. Alloying Au with the other metals could also improve its hydrogen evolution activity and the stability [10,17].…”

Gold-supported activated NiZn coatings: hydrogen evolution and corrosion studies

“…The reduction in the -η 100 at this electrode is 69% (with respect to the Cu/Ni/NiZn), which demonstrates that the presence of Au on the catalyst surface favours the hydrogen evolution kinetics and reduces the energy input for activating the HER [23,24]. However, the smallest Tafel slope appeared at the Au-modified electrode indicates a faster adsorption of H on the catalyst surface that leads to a faster HER rate [14,15]. Gold was Gold-supported activated NiZn coatings: HER and corrosion studies R. Solmaz reported to be a poor electrocatalyst for the HER because of the weak bond with H; namely, this metal is a poor substrate for hydrogen adsorption [12,24].…”

“…Gold was Gold-supported activated NiZn coatings: HER and corrosion studies R. Solmaz reported to be a poor electrocatalyst for the HER because of the weak bond with H; namely, this metal is a poor substrate for hydrogen adsorption [12,24]. However, the smallest Tafel slope appeared at the Au-modified electrode indicates a faster adsorption of H on the catalyst surface that leads to a faster HER rate [14,15]. Figure 2c shows the representative Nyquist plots of the working electrodes at À0.100-V overpotential.…”

“…In literature, there are only some studies on the hydrogen evolution activity of balk or nanostructured Au/or Au alloys [10][11][12][13][14][15][16][17]. Promising results could be obtained by the Au-nanoparticles or clusters [14][15][16][17] because more active centres are available on these surfaces. Alloying Au with the other metals could also improve its hydrogen evolution activity and the stability [10,17].…”

Gold-supported activated NiZn coatings: hydrogen evolution and corrosion studies

“…After 5000 CV cycles, the microstructures of Ag/WO 3− x heterostructures show obvious change, in which many pores appeared in the WO 3− x nanosheets (Figure a,b). These pores may be formed via the surface atom reorientation caused by the electrochemical cycling process, which can be due to the induction of electric field . Moreover, the STEM‐EDX elemental mappings show that W, O and Ag elements are homogeneously distributed in the porous nanostructure (Figure c).…”

Ultrathin, Porous and Oxygen Vacancies‐Enriched Ag/WO_3−x Heterostructures for Electrocatalytic Hydrogen Evolution

“…[9][10][11][12] It is becoming increasingly clear, however, that these types of pretreatments can significantly alter the properties of the catalysts under study. For example, following pretreatment, structured bimetallic NPs can undergo atomic rearrangements, [13][14][15][16] the crystal structure, shape, and facets can change, [4,[17][18][19] and atoms can undergo selective dissolution. [7,8,13,16,[20][21][22] Even for polycrystalline gold surfaces, the rate of anodic Au dissolution during potential cycling is highly dependent on the surface structure of the electrode.…”

Electrochemical Cleaning Stability and Oxygen Reduction Reaction Activity of 1‐2 nm Dendrimer‐Encapsulated Au Nanoparticles