Platinum Nanostructure/Nitrogen‐Doped Carbon Hybrid: Enhancing its Base Media HER/HOR Activity through Bi‐functionality of the Catalyst

Abstract The design and synthesis of an active catalyst for the hydrogen evolution reaction/hydrogen oxidation reaction (HER/HOR) are important for the development of hydrogen‐based renewable technologies. The synthesis of a hybrid of platinum nanostructures and nitrogen‐doped carbon [Pt‐(PtO x )‐NSs/C] for HER/HOR applications is reported herein. The HER activity of this Pt‐(PtO x )‐NSs/C catalyst is 4 and 6.5 times better than that of commercial Pt/C in acids and bases, respectively. The catalyst exhibits a current density of 10 mA cm −2 at overpotentials of 5 and 51 mV, with Tafel slopes of 29 and 64 mV dec −1 in 0.5  m H 2 SO 4 and 0.5  m KOH. This catalyst also showed superior HOR activity at all pH values. The HER/HOR activity of Pt‐(PtO x )‐NSs/C and PtO x ‐free Pt‐nanostructures on carbon (PtNSs/C) catalysts are comparable in acid. The presence of PtO x in Pt‐(PtO x )‐NSs/C makes this Pt catalyst more HER/HOR‐active in basic media. The activity of the Pt‐(PtO x )‐NSs/C catalyst is fivefold higher than that of the PtNSs/C catalyst in basic medium, although their activity is comparable in acid. The hydrogen‐binding energy and oxophilicity are two equivalent descriptors for HER/HOR in basic media. A bifunctional mechanism for the enhanced alkaline HER/HOR activity of the Pt‐(PtO x )‐NSs/C catalyst is proposed. In the bifunctional Pt‐(PtO x )‐NSs/C catalyst, PtO x provides an active site for OH − adsorption to form OH ads , which reacts with hydrogen intermediate (H ads ), present at neighbouring Pt sites to form H 2 O; this leads to enhancement of the HOR activity in basic medium. This work may provide an opportunity to develop catalysts for various renewable‐energy technologies.