The synthesis of palladium-based trimetallic catalysts via a facile and scalable synthesis procedure was shown to yield highly promising materials for borohydride-based fuel cells, which are attractive for use in compact environments. This, thereby, provides a route to more environmentally friendly energy storage
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The synthesis of palladium-based trimetallic catalysts via a facile and scalable synthesis procedure was shown to yield highly promising materials for borohydride-based fuel cells, which are attractive for use in compact environments. This, thereby, provides a route to more environmentally friendly energy storage and generation systems. Carbon-supported trimetallic catalysts were herein prepared by three different routes: using a NaBH
4-ethylene glycol complex (PdAuNi/C
SBEG), a NaBH
4-2-propanol complex (PdAuNi/C
SBIPA), and a three-step route (PdAuNi/C
3-step). Notably, PdAuNi/C
SBIPA yielded highly dispersed trimetallic alloy particles, as determined by XRD, EDX, ICP-OES, XPS, and TEM. The activity of the catalysts for borohydride oxidation reaction was assessed by cyclic voltammetry and RDE-based procedures, with results referenced to a Pd/C catalyst. A number of exchanged electrons close to eight was obtained for PdAuNi/C
3-step and PdAuNi/C
SBIPA (7.4 and 7.1, respectively), while the others, PdAuNi/C
SBEG and Pd/C
SBIPA, presented lower values, 2.8 and 1.2, respectively. A direct borohydride-peroxide fuel cell employing PdAuNi/C
SBIPA catalyst in the anode attained a power density of 47.5 mW cm
−2 at room temperature, while the elevation of temperature to 75 °C led to an approximately four-fold increase in power density to 175 mW cm
−2. Trimetallic catalysts prepared via this synthesis route have significant potential for future development.
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