Simple Physical Mixing of Graphitic Wood-Derived Carbon For High-Performance Ni(OH)2 Electrodes: A Sustainable Strategy Beyond Metal Additives.
Xingyan Zhang, Sadaf Saeedi Garakani, Gunder Karlsson, Dag Noréus
Abstract
Open AccessThe replacement of expensive metal powders in Ni-(OH)2-based cathodes is essential for reducing cost and environmental impact in aqueous Ni-Zn batteries. This work investigates graphitic wood-derived carbon (GWC) as a sustainable conductive additive to boost the performance of Ni-(OH)2 pasted electrodes prepared by a simple physical mixing process. A number of graphitic wood-derived carbon qualities are explored as functional additives replacing expensive cobalt and nickel powder additives while maintaining the electrochemical performance of Ni-(OH)2 electrodes in aqueous rechargeable Ni-Zn batteries. The GWC offers high electrical conductivity and a unique microsized particulate morphology. Optimizing the GWC content to 25 wt % yields a specific capacity of 284.2 mAh g-1 at 0.2C, which is better than that of electrodes containing only Ni-(OH)2, with Ni/Co powders, or commercial carbon black. Furthermore, the open-circuit voltage hysteresis and state of charge are studied to understand the charge/discharge process, suggesting that GWC is an effective alternative to expensive metal powders, providing a low-cost and sustainable strategy for improving Ni-(OH)2-based electrodes through a straightforward manufacturing process.