Phase transitions in a non-Hermitian Aubry-Andr\'e-Harper model

Abstract

The Aubry-Andr\'e-Harper model provides a paradigmatic example of aperiodic order in a one-dimensional lattice displaying a delocalization-localization phase transition at a finite critical value Vc of the quasiperiodic potential amplitude V. In terms of dynamical behavior of the system, the phase transition is discontinuous when one measures the quantum diffusion exponent δ of wave packet spreading, with δ=1 in the delocalized phase V<Vc (ballistic transport), δ 1/2 at the critical point V=Vc (diffusive transport), and δ=0 in the localized phase V>Vc (dynamical localization). However, the phase transition turns out to be smooth when one measures, as a dynamical variable, the speed v(V) of excitation transport in the lattice, which is a continuous function of potential amplitude V and vanishes as the localized phase is approached. Here we consider a non-Hermitian extension of the Aubry-Andr\'e-Harper model, in which hopping along the lattice is asymmetric, and show that the dynamical localization-delocalization transition is discontinuous not only in the diffusion exponent δ, but also in the speed v of ballistic transport. This means that, even very close to the spectral phase transition point, rather counter-intuitively ballistic transport with a finite speed is allowed in the lattice. Also, we show that the ballistic velocity can increase as V is increased above zero, i.e. surprisingly disorder in the lattice can result in an enhancement of transport.