Li-N2 Batteries: A Reversible Energy Storage System?

Abstract

Tremendous energy consumption is required for traditional artificial N₂ fixation, leading to additional environmental pollution. Recently, new Li-N₂ batteries have inextricably integrated energy storage with N₂ fixation. In this work, graphene is introduced into Li-N₂ batteries and enhances the cycling stability. However, the instability and hygroscopicity of the discharge product Li₃ N lead to a rechargeable but irreversible system. Moreover, strong nonpolar N≡N covalent triple bonds with high ionization energies also cause low efficiency and irreversibility of Li-N₂ batteries. In contrast, the modification with in situ generated Li₃ N and LiOH restrained the loss and volume change of Li metal anodes during stripping and plating, thereby promoting the rechargeability of the Li-N₂ batteries. The mechanistic study here will assist in the design of more stable Li-N₂ batteries and create more versatile methods for N₂ fixation.

Keywords: batteries; energy storage; graphene; nitrogen fixation; surface analysis.