Pressure-induced liquid-liquid transition in a family of ionic materials.
Zaneta WojnarowskaShinian ChengBeibei YaoMalgorzata Swadzba-KwasnyShannon McLaughlinAnne McGroganYoan M DelavouxMarian PaluchPublished in: Nature communications (2022)
Liquid-liquid transition (LLT) between two disordered phases of single-component material remains one of the most intriguing physical phenomena. Here, we report a first-order LLT in a series of ionic liquids containing trihexyl(tetradecyl)phosphonium cation [P 666,14 ] + and anions of different sizes and shapes, providing an insight into the structure-property relationships governing LLT. In addition to calorimetric proof of LLT, we report that ion dynamics exhibit anomalous behavior during the LLT, i.e., the conductivity relaxation times (τ σ ) are dramatically elongated, and their distribution becomes broader. This peculiar behavior is induced by isobaric cooling and isothermal compression, with the τ σ (T LL ,P LL ) constant for a given system. The latter observation proves that LLT, in analogy to liquid-glass transition, has an isochronal character. Finally, the magnitude of discontinuity in a specific volume at LLT was estimated using the Clausius-Clapeyron equation.