Abstract
"Fluid polyamorphism" is the existence of different condensed amorphous states in a single-component fluid. It is either found or predicted, usually at extreme conditions, for a broad group of very different substances, including helium, carbon, silicon, phosphorous, sulfur,tellurium, cerium, hydrogen and tin tetraiodide. This phenomenon is also hypothesized for metastable and deeply supercooled water, presumably located a few degrees below the experimental limit of homogeneous ice formation. We present a generic phenomenological approach to describe polyamorphism in a single-component fluid, which is completely independent of the molecular origin of the phenomenon. We show that fluid polyamorphism may occur either in the presence or the absence of fluid phase separation depending on the symmetry of the order parameter. In the latter case, it is associated with a second-order transition, such as in liquid helium or liquid sulfur. To specify the phenomenology, we consider a fluid with thermodynamic equilibrium between two distinct interconvertible states or molecular structures. A fundamental signature of this concept is the identification of the equilibrium fraction of molecules involved in each of these alternative states. However, the existence of the alternative structures may result in polyamorphic fluid phase separation only if mixing of these structures is not ideal. The two-state thermodynamics unifies all the debated scenarios of fluid polyamorphism in different areas of condensed-matter physics, with or without phase separation, and even goes beyond the phenomenon of polyamorphism by generically describing the anomalous properties of fluids exhibiting interconversion of alternative molecular states.
Highlights
Fluid polyamorphism is the existence of two or more amorphous condensed states in a single-component fluid [1,2,3,4,5,6]
We show that fluid polyamorphism may occur either in the presence or in the absence of fluid phase separation depending on the symmetry of the order parameter
A generic thermodynamic description of fluid polyamorphism can be formulated by using the Landau theory of phase transitions [39], in which the key concept is the order parameter, a variable that characterizes the emergence of a more ordered state
Summary
Fluid polyamorphism is the existence of two or more amorphous condensed states in a single-component fluid [1,2,3,4,5,6]. Fluid polyamorphism is found or predicted in a broad group of very different systems, including (but not limited to) helium [8,9], sulfur [10,11,12], phosphorous [13], carbon [14], cerium [15], silicon [16,17,18,19], silicon dioxide [20,21,22], tellurium [23,24,25], tin tetraiodide [26,27], and hydrogen [28,29,30] It has been hypothesized in metastable and deeply supercooled water [31,32,33,34,35,36]. Such coexistence has been reported for some atomistic water models (see review [36]), most notably
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