Fictitious phase separation in Li layered oxides driven by electro-autocatalysis

• Published in: Nature materials Vol. 20; no. 7; pp. 991 - 999
• Main Authors: Park, Jungjin, Zhao, Hongbo, Kang, Stephen Dongmin, Lim, Kipil, Chen, Chia-Chin, Yu, Young-Sang, Braatz, Richard D., Shapiro, David A., Hong, Jihyun, Toney, Michael F., Bazant, Martin Z., Chueh, William C.
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 01.07.2021; Nature Publishing Group
• Subjects: 639/301/299/161/886; 639/301/299/891; Anomalies; Autocatalysis; Biomaterials; Chemical reactions; Chemistry and Materials Science; Condensed Matter Physics; Control stability; Data transmission; Diffraction; Dynamic stability; Electrochemistry; Electrodes; Irreversible processes; Lithium; Lithium-ion batteries; Materials Science; Nanotechnology; Optical and Electronic Materials; Oxidation; Oxides; Particles; Phase composition; Phase separation; Phase transitions; Rechargeable batteries; Transition metals
• ISSN: 1476-1122; 1476-4660
• DOI: 10.1038/s41563-021-00936-1

Layered oxides widely used as lithium-ion battery electrodes are designed to be cycled under conditions that avoid phase transitions. Although the desired single-phase composition ranges are well established near equilibrium, operando diffraction studies on many-particle porous electrodes have suggested phase separation during delithiation. Notably, the separation is not always observed, and never during lithiation. These anomalies have been attributed to irreversible processes during the first delithiation or reversible concentration-dependent diffusion. However, these explanations are not consistent with all experimental observations such as rate and path dependencies and particle-by-particle lithium concentration changes. Here, we show that the apparent phase separation is a dynamical artefact occurring in a many-particle system driven by autocatalytic electrochemical reactions, that is, an interfacial exchange current that increases with the extent of delithiation. We experimentally validate this population-dynamics model using the single-phase material Li x (Ni 1/3 Mn 1/3 Co 1/3 )O 2 (0.5 <  x  < 1) and demonstrate generality with other transition-metal compositions. Operando diffraction and nanoscale oxidation-state mapping unambiguously prove that this fictitious phase separation is a repeatable non-equilibrium effect. We quantitatively confirm the theory with multiple-datastream-driven model extraction. More generally, our study experimentally demonstrates the control of ensemble stability by electro-autocatalysis, highlighting the importance of population dynamics in battery electrodes (even non-phase-separating ones). Although layered oxides electrodes in lithium-ion batteries are designed under conditions avoiding phase transitions, phase separation during delithiation has been observed. This apparent phase separation is shown to be a dynamical artefact occurring in a many-particle system driven by autocatalytic electrochemical reactions.