Inner-Sphere Electron Transfer Enabling Highly Reversible Mn<sup>2+</sup>/MnO<sub>2</sub> Conversion toward Energy-Dense Electrolytic Zinc–Manganese Batteries
Weijie Fan, Siyu Tian, Liping Qin, Taghrid S. Alomar, Pengchao Ruan, Zeinhom M. El‐Bahy, Najla AlMasoud, Bingan Lu, Jiang Zhou
Abstract
High-voltage electrolytic Zn//MnO 2 batteries show great potential for large-scale energy storage due to their affordability, eco-friendliness and high safety. However, their practical application is hindered by capacity losses due to incomplete MnO 2 dissolution. Herein, we propose the strategy by coupling a 1,4-benzoquinone (1,4-BQ)/hydroquinone (HQ) redox mediator pair with in situ modulation of MnO 2 electronic structure through electrolyte engineering to facilitate rapid and complete MnO 2 dissolution. During the charging and discharging processes, Al 3+ ions in the electrolyte enter MnO 2 lattice by co-deposition and intercalation, respectively. The incorporated Al 3+ ions effectively optimize the electronic structure of MnO 2 by lowering the valence state of localized Mn IV to Mn III, thereby facilitating the formation of inner-sphere complexes with HQ molecules. This transformation successfully shifts the dominant reaction mechanism between MnO 2 and the redox mediator from outer-sphere electron transfer (Mn IV –HQ) to inner-sphere electron transfer (Mn III –HQ). Consequently, complete MnO 2 dissolution can be achieved in the designed electrolyte even at an ultrahigh areal capacity of 50 mAh cm –2 . Furthermore, a 750-mAh electrolytic Zn//MnO 2 battery exhibits a capacity retention rate of 99% after 100 cycles, demonstrating the significance of regulating electron transfer mechanisms during MnO 2 dissolution through electrolyte coupling strategies.