Journal
SMALL
Volume 19, Issue 26, Pages -Publisher
WILEY-V C H VERLAG GMBH
DOI: 10.1002/smll.202208077
Keywords
electrocatalysis; hydrogen evolution reaction; molybdenum sulfide; ultrathin nanodendrites
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Surface modification of electrocatalysts is a key strategy for designing advanced nanocatalysts with improved electrocatalytic performance. This study develops highly dispersed amorphous molybdenum trisulfide-anchored Platinum nanodendrites (Pt-a-MoS3 NDs) as efficient hydrogen evolution electrocatalysts. The enhanced electrocatalytic activity of Pt catalysts is attributed to the highly dispersed a-MoS3, which acts as a preferred adsorption site for the efficient conversion of H+ to H2. Furthermore, the anchoring of highly dispersed clusters to Pt substrate significantly enhances the electrocatalytic stability.
Surface modification of electrocatalysts to obtain new or improved electrocatalytic performance is currently the main strategy for designing advanced nanocatalysts. In this work, highly dispersed amorphous molybdenum trisulfide-anchored Platinum nanodendrites (denoted as Pt-a-MoS3 NDs) are developed as efficient hydrogen evolution electrocatalysts. The formation mechanism of spontaneous in situ polymerization MoS42- into a-MoS3 on Pt surface is discussed in detail. It is verified that the highly dispersed a-MoS3 enhances the electrocatalytic activity of Pt catalysts under both acidic and alkaline conditions. The potentials at the current density of 10 mA cm(-2) (eta(10)) in 0.5 m sulfuric acid (H2SO4) and 1 m potassium hydroxide (KOH) electrolyte are -11.5 and -16.3 mV, respectively, which is significantly lower than that of commercial Pt/C (-20.2 mV and -30.7 mV). This study demonstrates that such high activity benefits from the interface between highly dispersed a-MoS3 and Pt sites, which act as the preferred adsorption sites for the efficient conversion of hydrion (H+) to hydrogen (H-2). Additionally, the anchoring of highly dispersed clusters to Pt substrate greatly enhances the corresponding electrocatalytic stability.
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