Abstract
One of the most intriguing anomalies of water is its ability to exist as distinct amorphous ice forms (glass polymorphism or polyamorphism). This resonates well with the possible first-order liquid-liquid phase transition (LLPT) in the supercooled state, where ice is the stable phase. In this Perspective, we review experiments and computer simulations that search for LLPT and polyamorphism in aqueous solutions containing salts and alcohols. Most studies on ionic solutes are devoted to NaCl and LiCl; studies on alcohols have mainly focused on glycerol. Less attention has been paid to protein solutions and hydrophobic solutes, even though they reveal promising avenues. While all solutions show polyamorphism and an LLPT only in dilute, sub-eutectic mixtures, there are differences regarding the nature of the transition. Isocompositional transitions for varying mole fractions are observed in alcohol but not in ionic solutions. This is because water can surround alcohol molecules either in a low- or high-density configuration whereas for ionic solutes, the water ion hydration shell is forced into high-density structures. Consequently, the polyamorphic transition and the LLPT are prevented near the ions, but take place in patches of water within the solutions. We highlight discrepancies and different interpretations within the experimental community as well as the key challenges that need consideration when comparing experiments and simulations. We point out where reinterpretation of past studies helps to draw a unified, consistent picture. In addition to the literature review, we provide original experimental results. A list of eleven open questions that need further consideration is identified.
Highlights
Vast amounts of research have been devoted to the study of aqueous solutions, filling more than five volumes of Franks’ water treatise.[4]
The behavior of aqueous solutions in the supercooled liquid or glass state (T o Tg), remains poorly understood. This lack of understanding is partially due to the fact that water exhibits glass polymorphism and may exist in more than one liquid state. It is an open question under what conditions a given aqueous solution may exhibit polyamorphism and/or a liquid–liquid phase transition (LLPT) at low temperatures
Aqueous solutions have been a traditional topic in physics and chemistry for centuries, the study of polyamorphism in aqueous solutions has only emerged in the third millennium
Summary
Vast amounts of research have been devoted to the study of aqueous solutions, filling more than five volumes of Franks’ water treatise.[4]. This lack of understanding is partially due to the fact that water exhibits glass polymorphism (polyamorphism) and may exist in more than one liquid state It is an open question under what conditions a given aqueous solution may exhibit polyamorphism and/or a liquid–liquid phase transition (LLPT) at low temperatures. Kauzmann temperature (TK),[63,64,65] at which the system is stuck in one basin of the potential energy landscape, thwarting any structural changes required for the transformation between LDL and HDL In this scenario the LLCP is directly connected with the presence of the r, cp, and kT maxima/minima lines in liquid water (see Fig. 1). The occurrence of this fragile to strong dynamical crossover (FSDC) in supercooled water is consistent with experiments.[81,82,83,84]
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