Universal high-frequency behavior of periodically driven systems: from dynamical stabilization to Floquet engineering Article Swipe

View

Related Concepts

Floquet theory Hamiltonian (control theory) Quasiperiodicity Observable Physics Dissipative system Classical mechanics Quantum mechanics Quasiperiodic function Theoretical physics Mathematics Nonlinear system Condensed matter physics Mathematical optimization

Marin Bukov , Luca D’Alessio , Anatoli Polkovnikov ·

YOU? · · 2015 · Open Access · · DOI: https://doi.org/10.1080/00018732.2015.1055918 · OA: W1957416724

We give a general overview of the high-frequency regime in periodically\ndriven systems and identify three distinct classes of driving protocols in\nwhich the infinite-frequency Floquet Hamiltonian is not equal to the\ntime-averaged Hamiltonian. These classes cover systems, such as the Kapitza\npendulum, the Harper-Hofstadter model of neutral atoms in a magnetic field, the\nHaldane Floquet Chern insulator and others. In all setups considered, we\ndiscuss both the infinite-frequency limit and the leading finite-frequency\ncorrections to the Floquet Hamiltonian. We provide a short overview of Floquet\ntheory focusing on the gauge structure associated with the choice of\nstroboscopic frame and the differences between stroboscopic and\nnon-stroboscopic dynamics. In the latter case one has to work with dressed\noperators representing observables and a dressed density matrix. We also\ncomment on the application of Floquet Theory to systems described by static\nHamiltonians with well-separated energy scales and, in particular, discuss\nparallels between the inverse-frequency expansion and the Schrieffer-Wolff\ntransformation extending the latter to driven systems.\n