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in which ions transfer through the ceramic phase by means of vacancies or interstitials within the lattice. Typical examples of this are glass/glass–ceramic Li2S‐P2S5 and ceramic thio‐lithium superionic conductor (LISICON) Li4 − xGe1 − xPxS4 (0 < x < 1), which are the most promising electrolytes to increase ion conductivity up to 10−5 S/cm [117].

      The effects of ceramic fillers on the ionic conductivity of solid polymer systems have been discussed for quite many years. The published papers show that increasing the conductivity is the key parameter. Polymer‐ceramic composites offer superior mechanical properties and great conductivities. However, exploring ceramics materials is still a challenge.

      2.3.5 Ionic Liquid Polymer Electrolytes

Schematic illustration of a switchable single-molecule electrochromic device derived from a viologen-tethered triazolium-based poly(ionic liquid).

      Source: Puguan and Kim [128].

Schematic illustration of the synthesis of PIL-b-CD and PIL-Fc membranes and the hook-and-loop strategy for adhesion based on b-CD and Fc-modified PIL membrane surfaces.

      Source: Guo et al. [129].

      2.3.6 Gelatin‐Based Polymer Electrolytes

Schematic illustration of an ECD structure containing a gel electrolyte composition combining lithium iodide LiI in 1-butyl-3-methylimidazolium iodide (BMII) ionic liquid, triiodide I3-/I- redox mediator, and biodegradable gelatin.

      Source: Reproduced with permission of Danine et al. [134].

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