Mass production of Li4Ti5O12 with a conductive network via in situ spray pyrolysis as a long cycle life, high rate anode material for lithium ion batteries†
Abstract
Nanocrystalline Li4Ti5O12 with in situ incorporation of carbon and Ti3+ was synthesized by industry scalable in situ spray pyrolysis, producing crystal sizes ranging from 10 to 30 nm. Subsequent annealing in N2 preserved a proportion of the carbon from the precursor organic salts, predominantly on the Li4Ti5O12 grain boundaries, where it formed a conductive network. Such a situation would be expected to inhibit the growth of the primary Li4Ti5O12 crystals. The molecular-level uniformity of the precursor allows synthesis of Li4Ti5O12 with a significantly shorter heat treatment compared to conventional solid state reaction, which in turn saves energy during large-scale production. Notably, both the nanosized particles and the in situ incorporation of carbon and Ti3+ improve the rate capability. In rate capability measurements, stable and high capacity retention was observed from 0.5 C to 30 C. Spray pyrolyzed Li4Ti5O12 delivered a discharge capacity of 145.8 mA h gā1 at 10 C for up to 500 cycles. In the full battery tests with Li(Co0.16Mn1.84)O4 as cathode, it also showed excellent capacity and cycling stability, further indicating that spray pyrolyzed Li4Ti5O12 is a promising anode material for high power batteries.
- This article is part of the themed collection: Materials for Energy storage