English

Tuning towards dynamic freezing using a two-rate protocol

Strongly Correlated Electrons 2016-08-24 v1

Abstract

We study periodically driven closed quantum systems where two parameters of the system Hamiltonian are driven with frequencies ω1\omega_1 and ω2=rω1\omega_2=r \omega_1. We show that such drives may be used to tune towards dynamics induced freezing where the wavefunction of the state of the system after a drive cycle at time T=2π/ω1T= 2\pi/\omega_1 has almost perfect overlap with the initial state. We locate regions in the (ω1,r)(\omega_1 ,r) plane where the freezing is near exact for a class of integrable and a specific non-integrable model. The integrable models that we study encompass Ising and XY models in d=1d=1, Kitaev model in d=2d=2, and Dirac fermions in graphene and atop a topological insulator surface whereas the non-integrable model studied involves the experimentally realized one-dimensional (1D) tilted Bose-Hubbard model in an optical lattice. In addition, we compute the relevant correlation functions of such driven systems and describe their characteristics in the region of (ω1,r)(\omega_1,r) plane where the freezing is near-exact. We supplement our numerical analysis with semi-analytic results for integrable driven systems within adiabatic-impulse approximation and discuss experiments which may test our theory.

Keywords

Cite

@article{arxiv.1604.08384,
  title  = {Tuning towards dynamic freezing using a two-rate protocol},
  author = {Satyaki Kar and Bhaskar Mukherjee and K. Sengupta},
  journal= {arXiv preprint arXiv:1604.08384},
  year   = {2016}
}

Comments

v1: 9 pages 9 figs

R2 v1 2026-06-22T13:43:21.953Z