High-entropy oxychloride increasing the stability of Li–sulfur batteries

0572779 - ÚFCH JH 2024 RIV GB eng J - Journal Article
Zukalová, Markéta - Fabián, M. - Porodko, O. - Vinarčíková, Monika - Pitňa Lásková, Barbora - Kavan, Ladislav
High-entropy oxychloride increasing the stability of Li–sulfur batteries.
RSC Advances. Roč. 13, č. 25 (2023), s. 17008-17016. E-ISSN 2046-2069
R&D Projects: GA ČR(CZ) GA20-03564S
Institutional support: RVO:61388955
Keywords : TiO2 * Li-sulfur batteries * electrocatalysis * cathode * separator
OECD category: Physical chemistry
Impact factor: 3.9, year: 2022
Method of publishing: Open access

A novel lithiated high-entropy oxychloride Li0.5(Zn0.25Mg0.25Co0.25Cu0.25)0.5Fe2O3.5Cl0.5 (LiHEOFeCl) with spinel structure belonging to the cubic Fd[3 with combining macron]m space group is synthesized by a mechanochemical–thermal route. Cyclic voltammetry measurement of the pristine LiHEOFeCl sample confirms its excellent electrochemical stability and the initial charge capacity of 648 mA h g−1. The reduction of LiHEOFeCl starts at ca. 1.5 V vs. Li+/Li, which is outside the electrochemical window of the Li–S batteries (1.7/2.9 V). The addition of the LiHEOFeCl material to the composite of carbon with sulfur results in improved long-term electrochemical cycling stability and increased charge capacity of this cathode material in Li–S batteries. The carbon/LiHEOFeCl/sulfur cathode provides a charge capacity of 530 mA h g−1 after 100 galvanostatic cycles, which represents ca. 33% increase as compared to the charge capacity of the blank carbon/sulfur composite cathode after 100 cycles. This considerable effect of the LiHEOFeCl material is assigned to its excellent structural and electrochemical stability within the potential window of 1.7 V/2.9 V vs. Li+/Li. In this potential region, our LiHEOFeCl has no inherent electrochemical activity. Hence, it acts solely as an electrocatalyst accelerating the redox reactions of polysulfides. This can be beneficial for the performance of Li–S batteries, as evidenced by reference experiments with TiO2 (P90).

Permanent Link: https://hdl.handle.net/11104/0343347