Mechanical Stabilization of Solid Polymer Electrolytes through Gamma Irradiation

- The mechanical properties of PCL-PTMC copolymer electrolytes are characterized.
- Unstabilized electrolytes show viscous flow at low shear rates.
- γ-Irradiation effectively stabilizes the electrolytes through covalent crosslinking.
- A high ionic conductivity is retained after moderate γ-treatment.
- Li/LiFePO4 half-cells using the electrolytes are cycled at both r.t. and 80 °C.

Attaining sufficient mechanical stability is a challenge for high-performance solid polymer electrolytes, particularly at elevated temperatures. We have here characterized the viscoelastic properties of the non-polyether host material poly(ε-caprolactone-co-trimethylene carbonate) with and without incorporated LiTFSI salt. While this electrolyte material performs well at room temperature, at 80 °C the material is prone to viscous flow. Through γ-irradiation at a dose of 25 kGy, the material stabilizes such that it behaves as a rubbery solid even at low rates of deformation while retaining a high ionic conductivity necessary for use in solid-state Li batteries. The performance of the irradiated electrolyte was investigated in Li polymer half-cells (Li vs. LiFePO4) at both 80 °C and room temperature. In contrast with the notably stable battery performance at low temperatures using the non-irradiated material, during cycling of the irradiated electrolytes detrimental instabilities were noted at both 80 °C and room temperature. The possible effects of both radiation damage to the electrolyte and impaired interfacial contacts due to the crosslinking indicate that a different procedure may be necessary in order to stabilize these electrolytes for use in battery cells capable of stable long-term operation.

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