Recently,
alkaline polymer electrolytes have obtained widespread
attention because of their increasing application for energy storage
and conversion systems. In this work, a novel poly(ionic liquid) membrane
preserving liquid crystal (LC) nanostructures composited with layered
double hydroxide (LDH) was constructed. The LDH is in situ synthesized
using hexagonal LC as a nanoreactor and exhibits a hierarchical structure
in the membrane. The preserved LC nanostructures and in situ grown
LDHs in the LC phase provide organic and inorganic pathways for hydroxide
transport. The formation of continuous hydrogen bond networks among
the hydroxide groups on the surface of LDHs distributed in hexagonal
mesophases, and the positively charged imidazolium groups of the poly(ionic
liquid) backbone lead to a high hydroxide conductivity according to
the Grotthuss mechanism. Meanwhile, the hybrid membrane also exhibits
a low swelling degree, enhanced chemical stability, and a comparable
mechanical property. The novel combination of in situ synthesized
LDHs and LC nanostructures in a poly(ionic liquid) film provides a
feasible method to develop hybrid anion exchange membranes (AEMs)
with enhanced performances.