Periodically driven Rydberg chains with staggered detuning
Abstract
We study the stroboscopic dynamics of a periodically driven finite Rydberg chain with staggered () and time-dependent uniform (λ(t)) detuning terms using exact diagonalization (ED). We show that at intermediate drive frequencies (ωD), the presence of a finite results in violation of the eigenstate thermalization hypothesis (ETH) via clustering of Floquet eigenstates. Such clustering is lost at special commensurate drive frequencies for which ωd=n (n ∈ Z) leading to restoration of ergodicity. The violation of ETH in these driven finite-sized chains is also evident from the dynamical freezing displayed by the density-density correlation function at specific ωD. Such a correlator exhibits stable oscillations with perfect revivals when driven close to the freezing frequencies for initial all spin-down (|0) or Neel (| Z2, with up-spins on even sites) states. The amplitudes of these oscillations vanish at the freezing frequencies and reduces upon increasing ; their frequencies, however, remains pinned to / in the large limit. In contrast, for the | Z2 (time-reversed partner of | Z2) initial state, we find complete absence of such oscillations leading to freezing for a range of ωD; this range increases with . We also study the properties of quantum many-body scars in the Floquet spectrum of the model as a function of and show the existence of novel mid-spectrum scars at large . We supplement our numerical results with those from an analytic Floquet Hamiltonian computed using Floquet perturbation theory (FPT) and also provide a semi-analytic computation of the quantum scar states within a forward scattering approximation (FSA).
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