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Catalyst Design: Counter Anion Effect on Ni Nanocatalysts Anchored on Hollow Carbon Spheres.

Ryan O'ConnorBoitumelo J MatsosoVictor MashindiPumza MenteLebohang MacheliBeatriz D MorenoBryan P DoyleNeil J CovilleDean H Barrett
Published in: Nanomaterials (Basel, Switzerland) (2023)
Herein, the influence of the counter anion on the structural properties of hollow carbon spheres (HCS) support was investigated by varying the nickel metal precursor salts applied. TEM and SEM micrographs revealed the dimensional dependence of the HCS shell on the Ni precursor salt, as evidenced by thick (~42 nm) and thin (~23 nm) shells for the acetate and chloride-based salts, respectively. Importantly, the effect of the precursor salt on the textural properties of the HCS nanosupports (~565 m 2 /g Ni(acet) ) and ~607 m 2 /g NiCl ), influenced the growth of the Ni nanoparticles, viz for the acetate-( ca 6.4 nm)- and chloride ( ca 12 nm)-based salts, respectively. Further, XRD and PDF analysis showed the dependence of the reduction mechanism relating to nickel and the interaction of the nickel-carbon support on the type of counter anion used. Despite the well-known significance of the counter anion on the size and crystallinity of Ni nanoparticles, little is known about the influence of such counter anions on the physicochemical properties of the carbon support. Through this study, we highlight the importance of the choice of the Ni-salt on the size of Ni in Ni-carbon-based nanocatalysts.
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