We study suspensions of synthetic clay Laponite at very low ionic strength. We show the existence, for these charged disk-like particles, of a liquid-soft solid transition mainly driven by electrostatic repulsive interactions. Such a process defines a re-entrant transition line in the phase diagram. Location of this line is predicted using basic arguments. The structure is characterized by ultra-small-angle X-ray scattering (USAXS). Soft-solid suspensions show a correlation peak compatible with long-range electrostatic stabilization. Such a result strongly contrasts with the evolution of the scattering spectra for solid-like suspensions of Laponite at high ionic strength (above 10 −4 M). Close inspection of this correlation peak reveals that individual particle distribution is not homogeneous in space.Colloidal systems undergo phase transitions such as liquid-solid, order-disorder, sol-gel or glass transition [1-6], which are of important technical and scientific interest. Phase transitions involving, for example, purely repulsive interactions (the so-called Kirkwood-Alder transition [3]) are now well established [3][4][5][6] for spherical charged particles (latex, SiO 2 ). This is not the case for suspensions of charged disk-like colloids where the origin and the status of the so-called phase diagram are still under debate [7][8][9][10][11][12]. A demonstrative example is the case of Laponite, a synthetic smectite clay which can be considered, on average, as a hard disc having a thickness of 1nm, an average diameter of 300 Å and a bulk density of 2.65 • 10 6 kg/m 3 . This material has recently generated a good deal of experimental and theoretical studies [8][9][10][11][12][13][14][15][16][17][18][19]. Above an ionic strength of 10 −4 M, several authors have observed a transition line from a liquid to a soft solid when the solid concentration C (expressed as the mass of solid over the
This perspective reviews current strategies to decouple segmental motion and ionic conductivity for lithium polymer battery electrolytes, including an outlook for potential future improvements.
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