Insight into the Microstructures of Black Holes with Quantum-Triggered Violations

TL;DR

This paper explores how quantum anomalies affect the microstructure and thermodynamic behavior of charged AdS black holes using Ruppeiner geometry, revealing deviations from classical scaling laws.

Contribution

It introduces a geometric approach to analyze quantum-induced modifications in black hole microstructures, highlighting deviations from mean-field critical behavior.

Findings

Quantum anomalies cause violations of classical scaling laws.

Ruppeiner geometry reveals altered microstructure signatures.

Insights into quantum effects on black hole thermodynamics.

Abstract

In this study, we investigate the microstructures of a charged AdS (Anti-de Sitter) black hole exhibiting quantum anomalies through the lens of Ruppeiner geometry. Previous research has established that black holes undergo $P$-$V$ phase transitions and exhibit critical phenomena near their critical points, characterized by four critical exponents that typically obey scaling laws predicted by mean-field theory. However, recent findings have revealed that black holes with quantum anomalies can violate these scaling laws. Motivated by these discoveries, we employ Ruppeiner geometry to probe the thermodynamic fluctuations and gain insights into the microstructure of such black holes. Our analysis aims to elucidate how quantum effects modify the microscopic properties of spacetime, offering a novel perspective on the understanding of black hole thermodynamics.