Emergence of a thermal equilibrium in a subsystem of a pure ground state by quantum entanglement

Abstract

By numerically exact calculations of spin-1/2 antiferromagnetic Heisenberg models on small clusters, we demonstrate that quantum entanglement between subsystems A and B in a pure ground state of a whole system A+B can induce thermal equilibrium in subsystem A. Here, the whole system is bipartitoned with the entanglement cut that covers the entire volume of subsystem A. Temperature TA of subsystem A is not a parameter but can be determined from the entanglement von Neumann entropy SA and the total energy EA of subsystem A calculated for the ground state of the whole system. We show that temperature TA can be derived by minimizing the relative entropy for the reduced density matrix operator of subsystem A and the Gibbs state (i.e., thermodynamic density matrix operator) of subsystem A with respect to the coupling strength between subsystems A and B. Temperature TA is essentially identical to the thermodynamic temperature, for which the entropy and the internal energy evaluated using the canonical ensemble in statistical mechanics for the isolated subsystem A agree numerically with the entanglement entropy SA and the total energy EA of subsystem A.Fidelity calculations ascertain that the reduced density matrix operator of subsystem A for the pure but entangled ground state of the whole system A+B matches, within a maximally 1.5\% error in the finite size clusters studied, the thermodynamic density matrix operator of subsystem A at temperature TA. We argue that quantum fluctuation in an entangled pure state can mimic thermal fluctuation in a subsystem. We also provide two simple but nontrivial analytical examples of free bosons and free fermions for which these statements are exact. We furthermore discuss implications and possible applications of our finding.