Residual Entropy of Glasses and the Third Law Expression

TL;DR

This paper resolves longstanding inconsistencies in the third law of thermodynamics related to glasses by defining thermodynamic coordinates as atomic positions, establishing a rigorous expression that accounts for residual entropy at zero temperature.

Contribution

It introduces a new framework for understanding entropy in solids by identifying atomic positions as thermodynamic coordinates, providing a consistent third law expression that includes residual entropy.

Findings

Residual entropy is due to frozen atomic configurations at low temperatures.

Thermodynamic coordinates are atomic positions, not structure-dependent.

A rigorous third law expression accounts for residual entropy without exceptions.

Abstract

The third law of thermodynamics dictates that the entropy of materials becomes zero as temperature ($T$) approaches zero. Contrarily, glass and other similar materials exhibit nonzero entropy at $T=0$, which contradicts the third law. For over a century, it has been a common practice to evade this problem by regarding glass as nonequilibrium. However, this treatment causes many inconsistencies in thermodynamics theory. This paper provides resolutions to these inconsistencies and provides a rigorous expression of the third law without any exception. To seek the entropy origin, the anthropomorphic feature of entropy must be resolved. Because entropy can be uniquely determined only when thermodynamic coordinates (TCs) are specified, we have to know which are TCs. This requires the reconsideration of the definition of equilibrium for solids in an unambiguous way, which does not depend on the solid structure. On this basis, it is deduced that TCs of solids are the equilibrium positions of atoms. TCs comprise a thermodynamic space, on which a unique value can be assigned to the entropy. For solids, equilibrium states are specified by discrete points in the thermodynamic space, which define atom configurations. Among various atom configurations, only one is thermally activated at sufficiently low temperatures, and others are called frozen configuration, which do not contribute to the temperature dependence of entropy in that region. The rigorous statement of the third law has been established by expressing that the entropy associated with the active configuration vanishes at $T=0$. Residual entropy arises when the entropy is evaluated on an extended space including the frozen configurations, which were previously active at high temperatures. The reconciliation of the two different views is explained through several debates on the glass transition.