English

Group-velocity slowdown in a double quantum-dot molecule

Mesoscale and Nanoscale Physics 2014-04-11 v1 Optics

Abstract

The slowdown of optical pulses due to quantum-coherence effects is investigated theoretically for an "active material" consisting of InGaAs-based double quantum-dot molecules. These are designed to exhibit a long lived coherence between two electronic levels, which is an essential part of a quantum coherence scheme that makes use of electromagnetically-induced transparency effects to achieve group velocity slowdown. We apply a many-particle approach based on realistic semiconductor parameters that allows us to calculate the quantum-dot material dynamics including microscopic carrier scattering and polarisation dephasing dynamics. The group-velocity reduction is characterized in the frequency domain by a quasi-equilibrium slow-down factor and in the time domain by the probe-pulse slowdown obtained from a calculation of the spatio-temporal material dynamics coupled to the propagating optical field. The group-velocity slowdown in the quantum-dot molecule is shown to be substantially higher than what is achievable from similar transitions in typical InGaAs-based single quantum dots. The dependences of slowdown and shape of the propagating probe pulses on lattice temperature and drive intensities are investigated.

Keywords

Cite

@article{arxiv.1404.2780,
  title  = {Group-velocity slowdown in a double quantum-dot molecule},
  author = {Stephan Michael and Weng W. Chow and Hans Christian Schneider},
  journal= {arXiv preprint arXiv:1404.2780},
  year   = {2014}
}

Comments

14 pages, 15 figures

R2 v1 2026-06-22T03:47:52.068Z