Abstract
The exploitation of high-efficient and cheap bifunctional cathode electrocatalyst is of significant importance to rechargeable zinc-air battery. In this paper, bimetallic sulfide coupled with CNTs ((Co, Mg)S2@CNTs) hybrid catalyst is developed via a proposed vulcanization process. The (Co, Mg)S2@CNTs) with controllable Mg substitution has a tailored crystal structure (amorphous and crystalline), which catalyzes oxygen reduction/evolution reaction (ORR/ OER), respectively. The active sites of CoS2@CNTs are activated by doping Mg ions, which accelerates the kinetics of the oxygen adsorption for ORR and oxygen desorption for OER. Meanwhile, the hybrid catalyst exhibits a unique hierarchal morphology and "catalytic buffer", which further accelerate the mass transfer of catalytic processes. In addition, the outer wall of CNTs as substrate effectively avoids the agglomeration of (Co, Mg)S2 particles by reasonably providing adsorption sites. The inter and outer walls of CNTs forms a high-speed conduction pathway, quickly transferring the electrons produced by oxygen catalytic reactions. As a result, the (Co, Mg)S2@CNTs exhibits an ORR performance comparable with commercial catalyst Pt/C-RuO2 and remarkable OER performance (Ej=10=1.59V). The high power density of 268 mW cm-2 and long-term charge/discharge-stability of the zinc-air battery proves the feasibility of (Co, Mg)S2@CNTs application in high power devices.
Published Version
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