SOLID-STATE BATTERY, HALIDE SOLID ELECTROLYTE AND ELECTRICAL DEVICE
A solid-state battery incorporates a high-entropy oxyhalide solid electrolyte as an additive within the positive active material layer, paired with a high-voltage positive electrode charged to a cutoff of at least 4.3 V. Combining several cations of differing valence raises the lattice disorder and oxidative stability of the electrolyte, improving Li+ transport and interfacial compatibility with the positive electrode during high-voltage cycling.
The electrolyte follows the composition Li3-2a-bAaBbCcDdEeOnCl6-m-2nFm, where A is a pentavalent metal (Ta, Nb, or V), B a tetravalent metal (Zr or Hf), and C, D, and E are three independent trivalent metals, with oxygen and fluorine partially replacing chlorine. In the worked embodiment Li1.4Ta0.5Zr0.3In0.1Y0.1Er0.1O0.5Cl4.9F0.1, precursor lithium salts and metal chlorides (TaCl5, ZrCl4, InCl3, YCl3, ErCl3) were ball-milled (500 rpm, 20 h) and annealed (200°C, 5 h, argon), giving particles of 0.3–5.2 μm. This electrolyte was blended with an LiNi0.83Co0.07Mn0.08O2 (Ni83) cathode and vapor-grown carbon fiber (70 : 27 : 3 by mass) and assembled against a Li-In electrode with a Li6PS5Cl sulfide separator layer.
Cells were cycled at 25°C between 2.8–4.8 V (vs. Li+/Li) after 0.1 C formation, then at 0.33 C. The Ni83 cell using Li1.4Ta0.5Zr0.3In0.1Y0.1Er0.1O0.5Cl4.9F0.1 as the cathode-layer additive exhibits a 50-cycle capacity retention of 98.79%, compared to 89.83% for an otherwise identical cell using conventional oxyhalide LiTaOCl4 and 90.17% for conventional halide LiTaCl6. No ionic conductivity data was identified.
