Abstract
Binary metal oxides are attractive anode materials for lithium-ion batteries. Despite sustained effort into nanomaterials synthesis and understanding the initial discharge mechanism, the fundamental chemistry underpinning the charge and subsequent cycles—thus the reversible capacity—remains poorly understood. Here, we use in operando X-ray pair distribution function analysis combining with our recently developed analytical approach employing Metropolis Monte Carlo simulations and non-negative matrix factorisation to study the charge reaction thermodynamics of a series of Fe- and Mn-oxides. As opposed to the commonly believed conversion chemistry forming rocksalt FeO and MnO, we reveal the two oxide series topotactically transform into non-native body-centred cubic FeO and zincblende MnO via displacement-like reactions whose kinetics are governed by the mobility differences between displaced species. These renewed mechanistic insights suggest avenues for the future design of metal oxide materials as well as new material synthesis routes using electrochemically-assisted methods.
Highlights
Binary metal oxides are attractive anode materials for lithium-ion batteries
Lithiation of MxOy begins with an insertion step at a higher voltage than the conversion process (c. 0.8 and 0.3 V for Fe and Mn, respectively) and is normally accompanied by electrolyte decomposition and other side reactions[15], which collectively give rise to the extra capacity seen in the first discharge
As the MnxOy pair distribution function (PDF) show little variation in the coherent length of the system—indicating comparable domain sizes of the hosting structure throughout the charge and subsequent discharge steps—we can infer the oxygen ordering likely remains essentially intact despite significant changes in the cation distribution
Summary
Binary metal oxides are attractive anode materials for lithium-ion batteries. Despite sustained effort into nanomaterials synthesis and understanding the initial discharge mechanism, the fundamental chemistry underpinning the charge and subsequent cycles— the reversible capacity—remains poorly understood. And importantly, a one-step conversion process from M to rs-MO upon charge was widely accepted in the field, we show that both FexOy and MnxOy undergo two steps via diffusioncontrolled displacement-like reactions, with O2− and Mn2+ as displaced species, respectively, for the Fe and Mn systems forming unexpected body-centred cubic (bcc) FeO and zincblende (zb) MnO.
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