α-VPO4: A Novel Many Monovalent Ion Intercalation Anode Material for Metal-Ion Batteries

In this paper, we report on a novel alpha-VPO4 phosphate adopting the alpha-CrPO4 type structure as a promising anode material for rechargeable metal-ion batteries. Obtained by heat treatment of a structurally related hydrothermally prepared KTiOPO4-type NH4VOPO4 pre-cursor under reducing conditions, the alpha-VPO4 material appears stable in a wide temperature range and possesses an interesting sponged needle-like particle morphology. The electrochemical performance of alpha-VPO4 as the anode material was examined in Li-, Na-, and K-based cells. The carbon coated alpha-VPO4/C composite exhibits 185, 110, and 37 mA h/g specific capacities respectively at the first discharge and around 120, 80, and 30 mA h/g at consecutive cycles at a C/10 rate. The considerable capacity drop after the first cycle in Li and Na cells is presumably due to irreversible alkali ion consumption taking place upon alkali-ion de/insertion. The EDX analysis of the recovered electrodes revealed an uptake of similar to 23% of Na after the first discharge with significant cell parameter alteration validated by operando XRD measurements. In contrast to the known beta-VPO4 anode materials, both Li and Na de/insertion into the new alpha-VPO4 proceed via an intercalation mechanism with the parent structural framework preserved but not via a conversion mechanism. The dimensionality of alkali-ion migration pathways and diffusion energy barriers was analyzed by the BVEL approach. Na-ion diffusion coefficients measured by the potentiostatic intermittent titration technique are in the range of (0.3-1.0).10(-10) cm(2)/s, anticipating alpha-VPO4 as a prospective high-power anode material for Na-ion batteries.