Scientific Reports (May 2023)

Phase transitions in the classical simulability of open quantum systems

  • F. Azad,
  • A. Hallam,
  • J. Morley,
  • A. G. Green

DOI
https://doi.org/10.1038/s41598-023-35336-9
Journal volume & issue
Vol. 13, no. 1
pp. 1 – 9

Abstract

Read online

Abstract We introduce a Langevin unravelling of the density matrix evolution of an open quantum system over matrix product states, which we term the time-dependent variational principle-Langevin equation. This allows the study of entanglement dynamics as a function of both temperature and coupling to the environment. As the strength of coupling to and temperature of the environment is increased, we find a transition where the entanglement of the individual trajectories saturates, permitting a classical simulation of the system for all times. This is the Hamiltonian open system counterpart of the saturation in entanglement found in random circuits with projective or weak measurements. If a system is open, there is a limit to the advantage in simulating its behaviour on a quantum computer, even when that evolution harbours important quantum effects. Moreover, if a quantum simulator is in this phase, it cannot simulate with quantum advantage.