English

The Floquet-Boltzmann equation

Quantum Gases 2015-12-16 v1

Abstract

Periodically driven quantum systems can be used to realize quantum pumps, ratchets, artificial gauge fields and novel topological states of matter. Starting from the Keldysh approach, we develop a formalism, the Floquet-Boltzmann equation, to describe the dynamics and the scattering of quasiparticles in such systems. The theory builds on a separation of time-scales. Rapid, periodic oscillations occurring on a time scale T0=2π/ΩT_0=2 \pi/\Omega, are treated using the Floquet formalism and quasiparticles are defined as eigenstates of a non-interacting Floquet Hamiltonian. The dynamics on much longer time scales, however, is modelled by a Boltzmann equation which describes the semiclassical dynamics of the Floquet-quasiparticles and their scattering processes. As the energy is conserved only modulo Ω\hbar \Omega, the interacting system heats up in the long-time limit. As a first application of this approach, we compute the heating rate for a cold-atom system, where a periodical shaking of the lattice was used to realize the Haldane model.

Keywords

Cite

@article{arxiv.1508.04551,
  title  = {The Floquet-Boltzmann equation},
  author = {Maximilian Genske and Achim Rosch},
  journal= {arXiv preprint arXiv:1508.04551},
  year   = {2015}
}

Comments

12 pages + 3 pages of appendix, 13 figures

R2 v1 2026-06-22T10:36:43.044Z