Conversion-Alloying Electrodes for Lithium-ion Batteries: Entropy and Nano-Level Heterogeneity Effects
Journal article, 2026
High entropy materials promise to overcome the instability and the degradation caused by large electrode volume variations
during (de-)lithiation, i.e. during (de-)charging of a lithium battery. Nano-level heterogeneity within such materials may,
however, affect the overall performance. Here, as proof-of-concept, low (GeTe, Sb2Te3) and medium ((SnSbBi)Te,
(SnSbBiGe)Te) entropy tellurides, as well as medium entropy composite tellurides ((SnSbBi)Te-ZnTe), (SnSbBiGe)Te-
Cu1.75Te)) have been explored for effects of entropy and heterogeneity on cycling stability and rate capability. The rate
capability is shown to depend on nano-level heterogeneity rather than entropy, but the latter to be important for stable
cycling; the medium entropy composite (SnSbBiGe)Te-Cu1.75Te renders up to 140 cycles with good capacity retention (87%)
and agreeable average coulombic efficiency (98.8 ± 0.4%). Altogether, characterizing and controlling nano-level
heterogeneity is crucially needed to improve performance and to optimize entropy-designed alloy electrodes.
during (de-)lithiation, i.e. during (de-)charging of a lithium battery. Nano-level heterogeneity within such materials may,
however, affect the overall performance. Here, as proof-of-concept, low (GeTe, Sb2Te3) and medium ((SnSbBi)Te,
(SnSbBiGe)Te) entropy tellurides, as well as medium entropy composite tellurides ((SnSbBi)Te-ZnTe), (SnSbBiGe)Te-
Cu1.75Te)) have been explored for effects of entropy and heterogeneity on cycling stability and rate capability. The rate
capability is shown to depend on nano-level heterogeneity rather than entropy, but the latter to be important for stable
cycling; the medium entropy composite (SnSbBiGe)Te-Cu1.75Te renders up to 140 cycles with good capacity retention (87%)
and agreeable average coulombic efficiency (98.8 ± 0.4%). Altogether, characterizing and controlling nano-level
heterogeneity is crucially needed to improve performance and to optimize entropy-designed alloy electrodes.
Author
Sajid Alvi
Chalmers, Physics, Materials Physics
Andrea Fazi
Chalmers, Physics, Microstructure Physics
Daniel Weber
Wallenberg Initiative Materials Science for Sustainability
Daniel Hedman
Institute for Basic Science - Korea (IBS)
Kriti Choudhary
University of Picardie Jules Verne
Olof Bäcke
Chalmers, Physics, Microstructure Physics
Farid Akhtar
Luleå University of Technology
Jean-Noel Chotard
University of Picardie Jules Verne
Mattias Thuvander
Chalmers, Physics, Microstructure Physics
Patrik Johansson
Chalmers, Physics, Materials Physics
EES Batteries
3033-4071 (ISSN) 3033-4071 (eISSN)
Vol. In PressNext Generation Batteries
Swedish Research Council (VR) (2021-00613), 2021-12-01 -- 2032-12-31.
Areas of Advance
Production
Subject Categories (SSIF 2025)
Materials Engineering
Infrastructure
Chalmers Materials Analysis Laboratory
DOI
10.1039/D6EB00032K