Issue 47, 2024

Regulating oxygen redox reactions in lithium-rich materials via an Al2O3-doped ZnO layer for enhanced stability and performance

Abstract

Lithium-rich materials (LRM), which hold promise as high-energy-density cathodes, face challenges due to irreversible oxygen evolution. This leads to rapid capacity decay and structural instability. In this work, a regulated oxygen redox reaction is achieved by constructing an ultrathin and uniform Al2O3-doped ZnO (AZO) layer on LRM (AZO–LRM). The AZO coating layer serves as a charge carrier layer that can generate an internal electric field, thereby suppressing the migration of anions. A space charge layer is formed at the interface between AZO and LRM due to electron transfer, significantly reducing the non-bonding orbital energy and restraining oxidation of surface oxygen in LRM. Benefiting from regulated oxygen redox, AZO–LRM shows reduced phase degradation and fewer side reactions, resulting in a thinner, improved cathode electrolyte interphase (CEI) and more complete layered structure, significantly enhancing Li-ion diffusion and reducing impedance. Consequently, AZO–LRM retains 91% of its capacity after 200 cycles and shows a 145 mA h g−1 capacity at a 5C rate. This work provides a universal and low-cost solution to oxygen evolution in LRM, offering a promising approach to overcome practical application challenges and highlighting the potential of doped oxides in high-voltage cathode materials.

Graphical abstract: Regulating oxygen redox reactions in lithium-rich materials via an Al2O3-doped ZnO layer for enhanced stability and performance

Supplementary files

Article information

Article type
Paper
Submitted
25 Sep 2024
Accepted
02 Nov 2024
First published
12 Nov 2024

J. Mater. Chem. A, 2024,12, 32871-32884

Regulating oxygen redox reactions in lithium-rich materials via an Al2O3-doped ZnO layer for enhanced stability and performance

X. Cheng, Y. Wang, J. Lu, W. Dai, H. Lei, J. Zuo, H. Li and Z. Fu, J. Mater. Chem. A, 2024, 12, 32871 DOI: 10.1039/D4TA06843B

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