Chains of magnetic ions in NH4+-intercalated vanadium pentoxide

Abstract

We explore the electronic and magnetic properties of NH4+-intercalated vanadium pentoxide (NH4+-V2O5), a material that has been identified as a promising cathode for aqueous zinc-ion batteries. Density Functional Theory (DFT) calculations incorporating the Hubbard U correction reveal that NH4+-V2O5 is an antiferromagnetic insulator with an energy gap of 1.97 eV. The introduction of NH4+ ions into the V2O5 structure results in significant structural distortions, leading to the formation of magnetic vanadium ions (V4+, 3d1) and non-magnetic ions (V5+, 3d0). The magnetic vanadium ions are organized into chains with antiferromagnetic order along the a-axis. Our findings indicate that NH4+-V2O5 exhibits strong electron correlation effects and negligible interchain magnetic interactions, rendering it a promising candidate for a one-dimensional magnetic van der Waals system. This work provides insights into the electronic and magnetic behaviors of NH4+-V2O5, with implications for its potential applications in energy storage technologies.

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