Slow dispersion in Floquet-Dirac Hamiltonians

TL;DR

This paper investigates slow dispersive decay in Floquet-Dirac Hamiltonians, providing a systematic method to construct examples with decay rates as slow as t^{-1/10}, extending previous results.

Contribution

It introduces a general ansatz and systematic procedure to construct Floquet-Dirac Hamiltonians with arbitrarily slow dispersive decay rates.

Findings

Constructed Hamiltonians with decay no faster than t^{-1/10}

Provided a systematic method for slow dispersion in non-autonomous systems

Suggested that arbitrarily slow decay t^{- extless}ε can be achieved

Abstract

We study dispersive decay for non-autonomous Hamiltonian systems. While the general theory for dispersion in such non-autonomous systems is largely open, it was shown \cite{kraisler2025time} that there exists a time-periodically forced one-dimensional Dirac equation with unusually slow dispersive decay rate of $t^{-1/5}$. It is to be expected that such behavior is not generic and requires a very particular forcing term; we provide a more general ansatz and systematic procedure to construct such an equation with a dispersive decay rate no faster than $t^{-1/10}$. Our limitations are purely algebraic and it stands to reason that arbitrarily slow decay, $t^{-\varepsilon}$ for every $\varepsilon > 0$, should be achievable.