Abstract
Density functional theory (DFT) calculations of 58 liquid elements at their triple point show that most metals exhibit near proportionality between thermal fluctuations between virial and potential-energy in the isochoric ensemble. This demonstrates a general "hidden" scale invariance of metals making the dense part of the thermodynamic phase diagram effectively one dimensional with respect to structure and dynamics. DFT computed density scaling exponents, related to the Gr{\"u}neisen parameter, are in good agreement with experimental values for 16 elements where reliable data were available. Hidden scale invariance is demonstrated in detail for magnesium by showing invariance of structure and dynamics. Computed melting curves of period three metals follow curves with invariance (isomorphs). The experimental structure factor of magnesium is predicted by assuming scale invariant inverse power-law (IPL) pair interactions. However, crystal packings of several transition metals (V, Cr, Mn, Fe, Nb, Mo, Ta, W and Hg), most post-transition metals (Ga, In, Sn, and Tl) and the metalloids Si and Ge cannot be explained by the IPL assumption. Thus, hidden scale invariance can be present even when the IPL-approximation is inadequate. The virial-energy correlation coefficient of iron and phosphorous is shown to increase at elevated pressures. Finally, we discuss how scale invariance explains the Gr{\"u}neisen equation of state and a number of well-known empirical melting and freezing rules.
Highlights
Scale invariance plays an important role in many branches of science
This demonstrates a general “hidden” scale invariance of metals making the condensed part of the thermodynamic phase diagram effectively one dimensional with respect to structure and dynamics
Strong correlations between virial and potential energy are, not necessarily a consequence of approximately scale-invariant pair interactions, but rather a property of the multidimensional energy function U (R,V ) per se. This fact motivates the present paper in which we show from first-principles computations that many metals possess hidden scale invariance at low pressure, i.e., when virtually uncompressed compared to the zero-pressure state
Summary
Scale invariance plays an important role in many branches of science. It greatly simplifies a given phenomenon by reducing the parameter space and introducing universalities over length or time scales. Some examples of this are the size distribution of earthquakes [1], Brownian motions of microscopic particles [2], cosmic microwave background radiation [3,4], and biological fractal structures [5] such as those of lung tissue or Romanesco broccoli. This paper establishes an approximate “hidden” scale invariance in the dense liquid part of the thermodynamic phase diagram of certain elements from ab initio computations. Hidden scale invariance implies a great simplification, namely that the thermodynamic phase diagram becomes effectively one dimensional
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