English

Functional renormalization group in Floquet space

Strongly Correlated Electrons 2016-12-21 v3

Abstract

We present an extension of the functional renormalization group to Floquet space, which enables us to treat the long time behavior of interacting time periodically driven quantum dots. It is one of its strength that the method is neither bound to small driving amplitudes nor to small driving frequencies, i.e. very general time periodic signals can be considered. It is applied to the interacting resonant level model, a prototype model of a spinless, fermionic quantum dot. The renormalization in several setups with different combinations of time periodic parameters is studied, where the numerical results are complemented by analytic expressions for the renormalization in the limit of small driving amplitude. We show how the driving frequency acts as an infrared cutoff of the underlying renormalization group flow which manifests in novel power laws. We utilize the tunability of the effective reservoir distribution function in a periodically driven onsite energy setup to show how its shape is directly reflected in the renormalization group flow. This allows to flexibly tune the power-law renormalization generically encountered in quantum dot structures. Finally, an in-phase quantum pump as well as a single parameter pump are investigated in the whole regime of driving frequency, demonstrating that the new power law in the driving frequency is reflected in the mean current of the latter.

Keywords

Cite

@article{arxiv.1609.02663,
  title  = {Functional renormalization group in Floquet space},
  author = {Anna Katharina Eissing and Volker Meden and Dante Marvin Kennes},
  journal= {arXiv preprint arXiv:1609.02663},
  year   = {2016}
}

Comments

16 pages, 9 figures

R2 v1 2026-06-22T15:44:37.290Z