A condensed-matter analogue of the false vacuum

TL;DR

This paper investigates a polar dielectric fluid cycle exhibiting negative-pressure and negative heat capacity, revealing a condensed-matter analogue of the false vacuum with implications for long-range energy interactions.

Contribution

It introduces a novel quasi-thermodynamic cycle based on negative-pressure states and demonstrates a condensed-matter analogue of the false vacuum, supported by experimental validation of thermodynamic equations.

Findings

Cycle operates between 37°C and 15°C under isochoric conditions.

Fluid exhibits negative heat capacity during cooling, leading to phase-change non-equivalence.

Classical thermodynamics accurately predicts equations of state but not cycle efficiency, indicating additional energy interactions.

Abstract

Through experimental investigation into the behaviour of a polar dielectric working fluid, an ideal quasi-thermodynamic cycle has been established. Particular stages of this cycle are described in terms of a condensed-matter analogue of the false vacuum, when operating under negative-pressure. The cycle is established between 37 degC and 15 degC under isochoric conditions. Phase-change work is created in two-directions, positive expansion-work and negative contraction-work. A large proportion of the expansion-work derives from a cooling process where the fluid exhibits negative heat capacity. When heat flux ceases, the fluid becomes unstable and heat capacity switches from negative to positive, displaying a non-equivalence of ensembles phase-change. Whilst elements of the fluid behaviour can only be described by the statistical mechanics of non-equilibrium systems, the calculated equations of state for classical thermodynamics are confirmed to be accurate from the experimental investigation. However, the classical thermodynamic calculations for cycle-efficiency do not produce a symmetry of energy conservation. This suggests that an additional form of energy, having long-range interaction and distinct from heat and work input, is involved in the performance of the quasi-thermodynamic cycle. The expansion of a negative-pressure fluid that contains inclusion compounds appears responsible for this potential energy interaction as an analogue of the false vacuum potential that can be explained by application of the virial theorem.