Scaling laws of out-of-time-order correlators in a non-Hermitian kicked rotor model

We investigate the dynamics of the out-of-time-order correlators (OTOCs) via a non-Hermitian extension of the quantum kicked rotor model, where the kicking potential satisfies PT -symmetry. The spontaneous PT -symmetry breaking emerges when the strength of the imaginary part of the kicking potential exceeds a threshold value. We find, both analytically and numerically, that in the broken phase of PT symmetry, the OTOCs rapidly saturate with time evolution. Interestingly, the late-time saturation value scales as a pow-law in the system size. The mechanism of such scaling law results from the interplay between the effects of the nonlocal operator in OTOCs and the time reversal induced by non-Hermitian-driven potential.

Automated summary

We investigate the dynamics of out-of-time-order correlators (OTOCs) in a non-Hermitian extension of the quantum kicked rotor model with PT-symmetry breaking. We find that in the broken PT-symmetry phase, the OTOCs rapidly saturate with time evolution and the saturation value scales as a power-law in the system size. This scaling law is a result of the interplay between the effects of nonlocal operators in OTOCs and the time reversal induced by the non-Hermitian-driven potential.