Identifying interfacial mechanisms limitations within aqueous Zn-MnO2 batteries and means to cure them with additives

Li-ion batteries are playing a key role within the field of electrical mobility, grid applications and related objects owing to their high energy densities and long lifetime, but their sustainability remains to be improved. Pushing in this direction, there is a rising interest towards rechargeable aqueous batteries. Great efforts are devoted to turn the primary alkaline zinc-manganese dioxide batteries that have dominated the primary battery applications into rechargeable systems. This turns out to be a colossal task owing to the complexity of the Zn-MnO2 chemistry that is not yet fully rationalized, thus causing delay in practical deployment. In this work, we revisit this chemistry by combining fundamental solution chemistry considerations and complementary analytical techniques (TEM, Raman spectroscopy and EQCM) together with the assembly of cells using either MnO2 or MnO2-free initial positive electrodes. We confirm the key role of the electrolyte together with the inseparable link between its pH and the system's electrochemical response. Moreover, during discharge and charge, we provide experimental evidence for the occurrence of MnO2 electrodissolution and back electrodeposition conjointly with the formation of soluble zinc hydroxides up to chemical precipitation and back dissolution of a Zn4SO4(OH)(6).xH(2)O phase. We show that this phase is essential in the buffering of the system's pH and demonstrate the beneficial role of its initial presence in the positive electrode composite. Further pushing the idea of buffering the pH of the elec-trolyte, we propose the use of additives such as ZnO, Mg(OH)2 or La(OH)(3) that enhance the capacity retention upon cycling, while slightly penalizing the cell capacity. These insights provide missing links regarding the interplay between the conjoint electrochemical-chemical reactions ruling the functioning of rechargeable Zn-MnO(2 )batteries, hence providing a step forward towards their development.

Automated summary

In this study, the chemistry of rechargeable zinc-manganese dioxide batteries was revisited through a combination of solution chemistry considerations and analytical techniques. The role of electrolyte and its pH in the electrochemical response of the system was confirmed. Experimental evidence for the occurrence of electrodissolution and electrodeposition of MnO2, as well as the formation of soluble zinc hydroxides and chemical precipitation, was provided. The presence of a specific phase was shown to be essential in buffering the system's pH and enhancing the capacity retention.