Non-Equilibrating a Black Hole with Inhomogeneous Quantum Quench (2112.14388v1)

Abstract: We study non-equilibrium processes in (1+1)-dimensional conformal field theory (CFT) after quantum quenches starting from the thermal equilibrium (Gibbs) state. Our quench protocol uses spatially inhomogeneous Hamiltonians, the Mobius and sine-square-deformed (SSD) Hamiltonians. After a quench by the Mobius Hamiltonian, physical quantities such as von Neumann entropy for subsystems exhibit periodic oscillations (quantum revival). On the other hand, there is no quantum revival after a quench using the SSD Hamiltonian. Instead, almost all the degrees of freedom of the system are asymptotically gathered at a single point, the fixed point of the SSD Hamiltonian. This results in a point-like excitation that carries as much information as the total thermal entropy -- like a black hole. We call this excitation a black-hole-like excitation. In contrast, parts of the system other than the fixed point approach the low-entropy (low-temperature) state at late times, and the reduced density matrix is given effectively by that of the ground state. When the CFT admits a holographic dual description, these quenches induce inhomogeneous deformations of the black hole in the bulk. In particular, after the quench by the SSD Hamiltonian, at late enough times, the horizon of the bulk black hole asymptotically "touches" the boundary. We also propose and demonstrate that our quench setups can be used to simulate the formation and evaporation processes of black holes, and create low-temperature states.