posted on 2016-11-17, 13:33authored byCarlos R. López-Barrón, Ru Chen, Norman J. Wagner
The emerging technologies involving
wearable electronics require
new materials with high stretchability, resistance to high loads,
and high conductivities. We report a facile synthetic strategy based
on self-assembly of concentrated solutions of end-functionalized PEO106–PPO70–PEO106 triblock
copolymer in ethylammonium nitrate into face-centered cubic micellar
crystals, followed by micelle corona cross-linking to generate elastomeric
ion gels (iono-elastomers). These materials exhibit an unprecedented
combination of high stretchability, high ionic conductivity, and mechanoelectrical
response. The latter consists of a remarkable and counterintuitive
increase in ion conductivity with strain during uniaxial extension,
which is reversible upon load release. Based on in situ SAXS measurements
of reversible crystal structure transformations during deformation,
we postulate that the origin of the conductivity increase is a reversible
formation of ion nanochannels due to a novel microstructural rearrangement
specific to this material.