2026-04-14T08:25:49Zhttps://recercat.cat/oai/request

oai:recercat.cat:2072/4741992025-04-03T10:27:19Zcom_2072_98col_2072_378192

00925njm 22002777a 4500 dc Creus, Jordi author Mallón, Laura author Romero Fernández, Nuria author Bofill Arasa, Roger author Moya, Alicia author Fierro, J.L.G. author Mas Balleste, Ruben author Sala Román, Xavier author Philippot, Karine author García-Antón, Jordi author 2019 Four different cathodes for the hydrogen evolution reaction (HER) have been developed by the decoration of commercial carbon microfibers with Ru nanoparticles (Ru NPs). Two types of carbon fibers have been used: pristine, as-received, carbon fibers (pCF) and carbon fibers modified by an oxidative treatment that led to the functionalization of their surface with carboxylic groups (fCF). The decoration of these CFs with Ru NPs has been performed by two different methodologies based on the organometallic approach: direct synthesis of Ru NPs on top of the CFs (in-situ Ru NPs) or impregnation of the CFs with a colloidal solution of preformed Ru NPs stabilized with 4-phenylpyridine (RuPP NPs; ex-situ Ru NPs). The electrocatalytic performance of these four cathodes (ex-situ RuPP@pCF and RuPP@fCF; in-situ Ru@pCF and Ru@fCF) for the HER has been studied in acidic conditions. The results obtained show that both the nature of the NPs and of the carbon fibers play a key role on the stability and activity of the hybrid electrodes: ex-situ prepared Ru NPs afford better activities at lower overpotentials and better stabilities than those formed in-situ. Among the two ex-situ systems, an enhancement of the stability with pCF is observed, that may arise from more effective π-interactions between 4-phenylpyridine ligand and the surface of these carbon fibers. This interaction is somehow disfavored with fCF due to the presence of the surface carboxylic groups. Carbon fibers Energy conversion Hydrogen evolution reaction Nanoparticles Ruthenium Ruthenium nanoparticles supported on carbon microfibers for hydrogen evolution electrocatalysis