Issue 13, 2024

Achieving stable lithium metal anodes via the synergy of electrostatic shielding and the high Li+ flux inorganic interphase

Abstract

Uncontrolled dendrite growth and slow Li+ transport kinetics at the anode/electrolyte interface severely hamper the practical applications of lithium metal batteries (LMBs). Herein, a high–charge density cationic polymer, poly(octaallyltetraazacyclo–decane nitrate) (POTA–NO3), was developed as an anodic protective layer to moderate Li+ deposition and enhance Li+ transport efficiency. According to Li+ deposition characteristics and simulation, POTA–NO3 with multiple positive charge sites provided excellent electrostatic shielding and enhanced Li+ desolvation process to the anodes. Meanwhile, anions generated a robust and high Li+ flux inorganic SEI to inhibit the polymer cationic layer and electrolyte decomposition. With the POTA–NO3 protective layer, Li||Li symmetric batteries achieved a stable cycling of 6300 h at a high current density of 5 mA cm−2 with a capacity of 5 mA h cm−2. Furthermore, the POTA–NO3-protected Li||LiCoO2 batteries exhibited a capacity retention of over 80% after 1400 long-term cycles at 1C. This work opens up the possibility for the development of stable lithium anodes.

Graphical abstract: Achieving stable lithium metal anodes via the synergy of electrostatic shielding and the high Li+ flux inorganic interphase

Supplementary files

Article information

Article type
Paper
Submitted
25 Janv. 2024
Accepted
20 Maijs 2024
First published
21 Maijs 2024

Energy Environ. Sci., 2024,17, 4519-4530

Achieving stable lithium metal anodes via the synergy of electrostatic shielding and the high Li+ flux inorganic interphase

J. Yu, X. Ma, X. Zou, Y. Hu, M. Yang, J. Yang, S. Sun and F. Yan, Energy Environ. Sci., 2024, 17, 4519 DOI: 10.1039/D4EE00399C

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