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Coexistence of (O<sub>2</sub>)<sup><i>n</i>−</sup> and Trapped Molecular O<sub>2</sub> as the Oxidized Species in P2-Type Sodium 3d Layered Oxide and Stable Interface Enabled by Highly Fluorinated Electrolyte

Chong Zhao, Chao Li, Hui Liu, Qing Qiu, Fushan Geng, Ming Shen, Wei Tong, Jingxin Li, Bingwen Hu

2021Journal of the American Chemical Society134 citationsDOI

Abstract

The interface stability of cathode/electrolyte for Na-ion layered oxides is tightly related to the oxidized species formed during the electrochemical process. Herein, we for the first time decipher the coexistence of (O2)n− and trapped molecular O2 in the (de)sodiation process of P2-Na0.66[Li0.22Mn0.78]O2 by using advanced electron paramagnetic resonance (EPR) spectroscopy. An unstable interface of cathode/electrolyte can thus be envisaged with conventional carbonate electrolyte due to the high reactivity of the oxidized O species. We therefore introduce a highly fluorinated electrolyte to tentatively construct a stable and protective interface between P2-Na0.66[Li0.22Mn0.78]O2 and the electrolyte. As expected, an even and robust NaF-rich cathode–electrolyte interphase (CEI) film is formed in the highly fluorinated electrolyte, in sharp contrast to the nonuniform and friable organic-rich CEI formed in the conventional lowly fluorinated electrolyte. The in situ formed fluorinated CEI film can significantly mitigate the local structural degeneration of P2-Na0.66[Li0.22Mn0.78]O2 by refraining the irreversible Li/Mn dissolutions and O2 release, endowing a highly reversible oxygen redox reaction. Resultantly, P2-Na0.66[Li0.22Mn0.78]O2 in highly fluorinated electrolyte achieves a high Coulombic efficiency (CE) of >99% and an impressive cycling stability in the voltage range of 2.0–4.5 V (vs Na+/Na) under room temperature (147.6 mAh g–1, 100 cycles) and at 45 °C (142.5 mAh g–1, 100 cycles). This study highlights the profound impact of oxidized oxygen species on the interfacial stability of cathode/electrolyte and carves a new path for building stable interface and enabling highly stable oxygen redox reaction.

Topics & Concepts

ElectrolyteChemistryElectrochemistryCathodeFaraday efficiencyOxideElectron paramagnetic resonanceReactivity (psychology)OxygenIonInorganic chemistryElectrodePhysical chemistryNuclear magnetic resonanceOrganic chemistryPhysicsMedicinePathologyAlternative medicineAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesSupercapacitor Materials and Fabrication
Coexistence of (O<sub>2</sub>)<sup><i>n</i>−</sup> and Trapped Molecular O<sub>2</sub> as the Oxidized Species in P2-Type Sodium 3d Layered Oxide and Stable Interface Enabled by Highly Fluorinated Electrolyte | Litcius