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Article Abstract
Organic ionic plastic crystal (OIPC) materials exhibit soft solid phases within a specific temperature range, making them promising candidates for various electrochemical devices due to their intrinsic ionic conductivity and electrochemical stability. In this study, a series of linear tris-pyrrolidinium salts with different alkyl side chain lengths and counter-anions were synthesized and systematically characterized in terms of their structural, thermal, and electrochemical properties. Among the synthesized compounds, N,N-bis(4-(N'-undecylpyrrolidinium)butyl)pyrrolidinium trishexafluorophosphate (11-PF) exhibited two solid-solid phase transitions and a low fusion entropy (ΔS) of 13 J·K·mol at 210 °C. Similarly, N,N-bis(4-(N'-dodecylpyrrolidinium)butyl)pyrrolidinium tris-hexafluorophosphate (12-PF) showed multiple phase transitions with a low ΔS of 18 J·K·mol at 206 °C. The temperature-dependent soft crystalline phases of 11-PF were identified as plastic crystal phase using polarized optical microscopy and 1D wide-angle X-ray scattering (WAXS). The ionic conductivity of 11-PF was measured to be 2.04 × 10 S·cm at 70 °C. Upon blending with 80 mol% LiTfN, the ionic conductivity significantly increased to 1.16 × 10 S·cm. Electrochemical stability was evaluated via linear sweep voltammetry (LSV). The composite solid electrolyte consisting of 11-PF and 80 mol% LiTfN exhibited electrochemical stability up to 5.4 V (versus Li/Li), highlighting its potential as a high-voltage electrolyte component.
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