Towards Sustainable Energy Storage: Evaluating Polymer Electrolytes for Zinc Ion Batteries

TL;DR

This study evaluates novel polymer electrolytes for zinc ion batteries, demonstrating improved stability, durability, and ionic conductivity, advancing the development of flexible, sustainable energy storage solutions.

Contribution

Introduces and compares three new polymer electrolytes for zinc ion batteries, highlighting their enhanced performance and durability over existing electrolytes.

Findings

PAM hydrogel electrolyte reduces LDH formation and protects zinc foil.

p-PBI membrane provides prolonged durability against short circuits.

Full-cell with PBI-T membrane shows highest capacity and stability.

Abstract

Polymer electrolytes present a promising solution to the challenges posed by aqueous electrolytes in energy storage systems, offering the flexibility needed for wearable electronics. Despite the increasing interest in polymer electrolyte-based zinc ion batteries (ZIBs), their development is still in its early stages due to various challenges. In this study, we fabricated three promising polymer electrolytes: CSAM (carboxyl methyl chitosan with acrylamide monomer), PAM (polyacrylamide monomer hydrogel electrolyte), and p-PBI (Phosphoric acid (PA)-doped polybenzimidazole) with Zn(ClO4)2 and Zn(OTf)2, for their application in zinc ion batteries. Our results demonstrated that PAM hydrogel electrolyte exhibited very low LDH formation after a long cycle, demonstrating effective protection for zinc foil, and the high mechanical stability of the p-PBI membrane provided prolonged durability against short circuits through the formation of LDH. The presence of carboxyl groups in CSAM and the formation of O-H bonding facilitated ion movement, resulting in enhanced ionic conductivity, and preventing dendrite formation. Incorporating these hydrogels with high-performance zinc salts, such as zinc triflate (Zn(OTf)2), resulted in impressive stability, with the symmetric cell demonstrating over 4000 hours of uniform and stable voltage profile under 1 mA/cm2 and low overpotential of around 53 mV cycling with CSAM. The full-cell battery with PBI-T membrane showed the highest durability and capacity compared to CSAM-T and PAM-T, due to the greater availability of free protons for storing zinc in the cathode.