Harris Matthew A, Kinsey Thomas, Wagle Durgesh V, Baker Gary A, Sangoro Joshua
Department of Chemical and Biomolecular Engineering, University of Tennessee, Knoxville, TN 37996.
Department of Chemistry and Physics, Florida Gulf Coast University, Fort Myers, FL 33965.
Proc Natl Acad Sci U S A. 2021 Mar 16;118(11). doi: 10.1073/pnas.2020878118.
A liquid-liquid transition (LLT) is a transformation from one liquid to another through a first-order transition. The LLT is fundamental to the understanding of the liquid state and has been reported in a few materials such as silicon, phosphorus, triphenyl phosphite, and water. Furthermore, it has been suggested that the unique properties of materials such as water, which is critical for life on the planet, are linked to the existence of the LLT. However, the experimental evidence for the existence of an LLT in many molecular liquids remains controversial, due to the prevalence and high propensity of the materials to crystallize. Here, we show evidence of an LLT in a glass-forming trihexyltetradecylphosphonium borohydride ionic liquid that shows no tendency to crystallize under normal laboratory conditions. We observe a step-like increase in the static dielectric permittivity at the transition. Furthermore, the sizes of nonpolar local domains and ion-coordination numbers deduced from wide-angle X-ray scattering also change abruptly at the LLT. We independently corroborate these changes in local organization using Raman spectroscopy. The experimental access to the evolution of local order and structural dynamics across a liquid-liquid transition opens up unprecedented possibilities to understand the nature of the liquid state.
液-液转变(LLT)是一种通过一级相变从一种液体转变为另一种液体的过程。液-液转变对于理解液态至关重要,并且已在一些材料中被报道,如硅、磷、亚磷酸三苯酯和水。此外,有人提出,对于地球上生命至关重要的水等材料的独特性质与液-液转变的存在有关。然而,由于许多分子液体结晶的普遍性和高倾向性,关于液-液转变存在的实验证据仍然存在争议。在此,我们展示了在一种玻璃形成性的三己基十四烷基鏻硼氢化物离子液体中存在液-液转变的证据,该离子液体在正常实验室条件下没有结晶倾向。我们观察到在转变时静态介电常数呈阶梯状增加。此外,从广角X射线散射推断出的非极性局部域的大小和离子配位数在液-液转变时也会突然变化。我们使用拉曼光谱独立证实了局部组织的这些变化。通过实验研究液-液转变过程中局部有序和结构动力学的演变,为理解液态的本质开辟了前所未有的可能性。