Statistical Multifragmentation in Thermodynamical Limit: An Exact Solution for Phase Transitions

TL;DR

This paper provides an exact analytical solution to the statistical multifragmentation model in the thermodynamic limit, revealing a first-order liquid-gas phase transition and exploring conditions for second-order transitions with implications for nuclear matter.

Contribution

It introduces an exact solution incorporating excluded volume effects and extends the model with Fisher's term, advancing understanding of nuclear liquid-gas phase transitions.

Findings

Identifies a first-order phase transition of the liquid-gas type.

Analyzes the mixed phase region with coexistence of gas and liquid.

Studies thermodynamic properties near phase boundaries, including caloric curve and specific heat.

Abstract

An exact analytical solution of the statistical multifragmentation model is found in thermodynamic limit. Excluded volume effects are taken into account in the thermodynamically self-consistent way. The model exhibits a 1-st order phase transition of the liquid-gas type. An extension of the model including the Fisher's term is also studied. The possibility of the second order phase transition at or above the critical point is discussed. The mixed phase region of the phase diagram, where the gas of nuclear fragments coexists with the infinite liquid condensate, is unambiguously identified. The peculiar thermodynamic properties of the model near the boundary between the mixed phase and the pure gaseous phase are studied. The results for the caloric curve and specific heat are presented and a physical picture of the nuclear liquid-gas phase transition is clarified.