Abstract
We present a theoretical method to generate a highly accurate {\em time-independent} Hamiltonian governing the finite-time behavior of a time-periodic system. The method exploits infinitesimal unitary transformation steps, from which renormalization group-like flow equations are derived to produce the effective Hamiltonian. Our tractable method has a range of validity reaching into frequency regimes that are usually inaccessible via high frequency $\omega$ expansions in the parameter $h/\omega$, where $h$ is the upper limit for the strength of local interactions. We demonstrate our approach on both interacting and non-interacting many-body Hamiltonians where it offers an improvement over the more well-known Magnus expansion and other high frequency expansions. For the interacting models, we compare our approximate results to those found via exact diagonalization. While the approximation generally performs better globally than other high frequency approximations, the improvement is especially pronounced in the regime of lower frequencies and strong external driving. This regime is of special interest because of its proximity to the resonant regime where the effect of a periodic drive is the most dramatic. Our results open a new route towards identifying novel non-equilibrium regimes and behaviors in driven quantum many-particle systems.
Highlights
Recent years have seen rapid progress in our understanding of dynamics and nonequilibrium phenomena in quantum systems [1,2]
For a more compact notation, we define S⊥i 1⁄4 ðSxi ; Syi ; 0Þ. We choose this model because the external magnetic field breaks magnetization conservation, and it allows us to see if the flow equation approach works under circumstances where the driving breaks a symmetry of the static part of the Hamiltonian
We have demonstrated the power of the flow equation approach by illustrating how one can reach into perturbatively inaccessible frequency regimes
Summary
Recent years have seen rapid progress in our understanding of dynamics and nonequilibrium phenomena in quantum systems [1,2]. It is notoriously difficult to calculate HF or the exact time-evolution operator UðtÞ for interacting systems, so generally one uses expansion techniques to find an approximate, effective Hamiltonian in the high-frequency limit. These techniques include the Magnus expansion [71,72,73], rotating frames [53], and many more [20,67,74,75,76,77,78,79,80].
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