Kinetics of a phase transition for a Kerr-AdS black hole on the free-energy landscape

TL;DR

This paper models the phase transition kinetics of Kerr-AdS black holes using a stochastic approach on the free energy landscape, revealing new bounds and dynamic behaviors of black hole states.

Contribution

It introduces a stochastic kinetic framework for black hole phase transitions, highlighting bounds on the order parameter and differences from previous models.

Findings

Extremal points of Gibbs free energy correspond to physical black holes.

The off shell Gibbs free energy shows a double well structure with equal depths.

Higher temperatures accelerate the phase transition process.

Abstract

By treating the order parameter as a stochastic thermal fluctuating variable for small-large black hole phase transition, we investigate the kinetic process of phase transition for the Kerr-AdS (anti-de Sitter) black holes on free energy landscape. We find that the extremal points of the off shell Gibbs free energy correspond to physical black holes. For small-large black hole phase transition, the off shell Gibbs free energy exhibits a double well behavior with the same depth. Contrary to previous research for the kinetics of phase transition for the Kerr-Newman-AdS family black holes on a free energy landscape, we find that there is a lower bound for the order parameter and the lower bound corresponds to extremal black holes. In particular, the off shell Gibbs free energy is zero instead of divergent as previous work suggested for vanishing black hole horizon radius, which corresponds to the Gibbs free energy of a thermal AdS space. The investigation for the evolution of the probability distribution for the phase transition indicates that the initial stable small (large) black hole tends to switch to stable large (small) black hole. Increasing the temperature along the coexistence curve, the switching process becomes faster and the probability distribution reaches the final stationary Boltzmann distribution at a shorter time. The distribution of the first passage time indicates the time scale of the small-large black hole phase transition, and the peak of the distribution becomes sharper and shifts to the left with the increase of temperature along the coexistence curve. This suggests that a considerable first passage process occurs at a shorter time for higher temperature. The investigation of the kinetics of phase transition might provide us new insight into the underlying microscopic interactions.