A perturbative renormalization group approach to driven quantum systems
Abstract
We use a perturbative momentum shell renormalization group (RG) approach to study the properties of a driven quantum system at zero temperature. To illustrate the technique, we consider a bosonic theory with an arbitrary time dependent interaction parameter , where is the drive frequency and derive the RG equations for the system using a Keldysh diagrammatic technique. We show that the scaling of is analogous to that of temperature for a system in thermal equilibrium and its presence provides a cutoff scale for the RG flow. We analyze the resultant RG equations, derive an analytical condition for such a drive to take the system out of the gaussian regime, and show that the onset of the non-gaussian regime occurs concomitantly with appearance of non-perturbative mode coupling terms in the effective action of the system. We supplement the above-mentioned results by obtaining them from equations of motions of the bosons and discuss their significance for systems near critical points described by time-dependent Landau-Ginzburg theories.
Cite
@article{arxiv.1308.4689,
title = {A perturbative renormalization group approach to driven quantum systems},
author = {Sangita De Sarkar and Rajdeep Sensarma and K. Sengupta},
journal= {arXiv preprint arXiv:1308.4689},
year = {2015}
}
Comments
v2 11pages 7 figs; minor changes from v1