Dynamical scaling symmetry and asymptotic quantum correlations for time-dependent scalar fields

Abstract: In time-independent quantum systems, entanglement entropy possesses an inherent scaling symmetry that the energy of the system does not have. The symmetry also assures that entropy divergence can be associated with the zero modes. We generalize this symmetry to time-dependent systems all the way from a coupled harmonic oscillator with a time-dependent frequency, to quantum scalar fields with time-dependent mass. We show that such systems have dynamical scaling symmetry that leaves the evolution of various meas… Show more

“…For a single time-dependent oscillator, this procedure has been used in [35] to find out the Nielsen complexity of the Lipkin-Meshkov-Glick model using the wave function method of [20], [28]. Recently, in [36] the solution of the EMP equation was also used to find out the complexity using the covariance matrix of a state and its comparison with the wavefunction method was also studied.…”

Evolution of circuit complexity in a harmonic chain under multiple quenches

“…For a single time-dependent oscillator, this procedure has been used in [35] to find out the Nielsen complexity of the Lipkin-Meshkov-Glick model using the wave function method of [20], [28]. Recently, in [36] the solution of the EMP equation was also used to find out the complexity using the covariance matrix of a state and its comparison with the wavefunction method was also studied.…”

Evolution of circuit complexity in a harmonic chain under multiple quenches