posted on 2024-02-07, 15:34authored byFaiz Ahmed, Anna Chen, M. Virginia P. Altoé, Gao Liu
Solid-state batteries (SSBs) that incorporate the argyrodite-Li6PS5Cl (LPSCl) electrolyte hold potential as substitutes
for conventional lithium-ion batteries (LIBs). However, the mismatched
interface between the LPSCl electrolyte and electrodes leads to increased
interfacial resistance and the rapid growth of lithium (Li) dendrites.
These factors significantly impede the feasibility of their widespread
industrial application. In this study, we developed a composite electrolyte
of the LPSCl/polymer to enhance the contact between the electrolyte
and electrodes and suppress dendrite formation at the grain boundary
of the LPSCl ceramic. The monomer, triethylene glycol dimethacrylate
(TEGDMA), is utilized for in situ polymerization through thermal curing
to create the argyrodite LPSCl/polymer composite electrolyte. Additionally,
the ball-milling technique was employed to modify the morphology and
particle size of the LPSCl ceramic. The ball-milled LPSCl/polymer
composite electrolyte demonstrates slightly higher ionic conductivity
(ca. 2.21 × 10–4 S/cm) compared to the as-received
LPSCl/polymer composite electrolyte (ca. 1.65 × 10–4 S/cm) at 25 °C. Furthermore, both composite electrolytes exhibit
excellent compatibility with Li-metal and display cycling stability
for up to 1000 h (375 cycles), whereas the as-received LPSCl and ball-milled
LPSCl electrolytes maintain stability for up to 600 h (225 cycles)
at a current density of 0.4 mA/cm2. The SSB with the ball-milled
LPSCl/polymer composite electrolyte delivers high specific discharge
capacity (138 mA h/g), Coulombic efficiency (99.97%), and better capacity
retention at 0.1C, utilizing the battery configuration of coated NMC811//electrolyte//Li-Indium
(In) at 25 °C.