Parity-time symmetry phase transition in photonic time-modulated media

Abstract

Time modulation can cause gain and loss in photonic media, leading to complex modal behaviors and enhanced wave controllability in the non-Hermitian regime. Conversely, we reveal that Hermiticity and parity-time PT-symmetry phase transition are possible under the temporal PT-symmetry in time-modulated photonic media. We prove that, for a homogeneously modulated photonic medium with complex-valued modulation, temporal PT-symmetry is a necessary but insufficient condition for obtaining a real eigenvalue spectrum, giving rise to PT-symmetry phase transition. Specifically, the PT phase transition critically depends on the contrast between the modulation depth of the real and imaginary parts of permittivity when they are sinusoidally modulated with a π/2 phase difference. We generalize the discretized temporal-interface transfer matrix method to a continuous differential operator framework, which facilitates the confirmation of the phase transition condition via Magnus expansion analysis. Full-wave simulations and analytical calculations jointly confirm the occurrence of PT-transition by examining the scattering behavior of a propagating pulse in such a type of modulated medium. The findings provide a temporal PT-symmetric paradigm for controlling Hermiticity and non-Hermiticity in spatiotemporal photonic systems.