Issue 18, 2024

Enhancing lithium storage rate and durability in sphalerite GeP by engineering configurational entropy

Abstract

Monoclinic GeP with a layered structure, featuring a large capacity, low plateau, and high initial coulombic efficiency (ICE), has been demonstrated as a promising alternative anode material for Li-ion batteries. However, its semiconductor feature and overutilization of expensive Ge pose a significant obstacle to its further advancement. To further improve electronic and Li-ionic conductivity, and reduce the cost, via a mechanochemical method, we synthesize a cubic GeP-based compound, ZnGeSiP3, which possesses a triple cation-mixed sphalerite lattice, affording metallic conductivity and rapid Li-ion diffusion, and thereby outperforms monoclinic GeP due to enhanced conformational entropy, as verified through theoretical calculations and experimental analyses. Various characterization techniques, such as operando X-ray diffraction (XRD), Raman spectroscopy, and X-ray photoelectron spectroscopy (XPS), confirm the reversible storage of Li-ions within ZnGeSiP3via intercalation and subsequent conversion reactions, yielding a notable reversible capacity of 1638 mA h g−1 with an ICE of 92% at 100 mA g−1. The graphite-modified ZnGeSiP3 composite exhibits exceptional long-term cycling stability, retaining 981 mA h g−1 after 1600 cycles at 2000 mA g−1, and ultrahigh rate performance, maintaining 568 mA h g−1 at 22 000 mA g−1, surpassing most previously studied anodes. Drawing inspiration from the favorable entropic effects, we synthesize high-entropy cation-mixed sphalerite-structured GeP-based compounds, including CuSnAlZnGeSiP6, CuSn (or Al)ZnGeSiP5, and SnAlZnGeSiP5, as well as quaternary cation-disordered sphalerite-structured GeP-based compounds of Cu (or Sn, or Al)ZnGeSiP4. Furthermore, we synthesize high-entropy sphalerite-structured GeP-based compounds ZnGeSiPSSe and ZnGeSiP2Se (or S) with disordered cationic and anionic compositions, effectively addressing the challenge of incompatible multiple anions and cations. The phase formation mechanisms of these sphalerite-structured GeP-based compounds can be attributed to their negative phase formation energies, benefiting from the elevated conformational entropy. Crucially, all the aforementioned sphalerite-structured GeP-based compounds have metallic conductivity and showcase superior electrochemical Li-storage properties, including high capacity, high ICE, small polarization loss, and suitable operating potential. Broadly, the high conformational entropy strategy can serve as a new design paradigm for high-performance and cost-effective anodes for LIBs and beyond.

Graphical abstract: Enhancing lithium storage rate and durability in sphalerite GeP by engineering configurational entropy

Supplementary files

Article information

Article type
Paper
Submitted
24 mar 2024
Accepted
09 iyl 2024
First published
08 avq 2024
This article is Open Access
Creative Commons BY-NC license

Energy Environ. Sci., 2024,17, 6533-6547

Enhancing lithium storage rate and durability in sphalerite GeP by engineering configurational entropy

Y. Li, J. Wang, T. Liu, X. Li, Z. Guo, M. Liu and W. Li, Energy Environ. Sci., 2024, 17, 6533 DOI: 10.1039/D4EE01329H

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