English

Electronic Coherence Control in a Charged Quantum Dot

Mesoscale and Nanoscale Physics 2016-01-27 v1

Abstract

Minimizing decoherence due to coupling of a quantum system to its fluctuating environment is at the forefront of quantum information science and photonics research. Nature sets the ultimate limit, however, given by the strength of the system's coupling to the electromagnetic field. Here, we establish the ability to electronically control this coupling and enhance\textit{enhance} the coherence time of a quantum dot excitonic state. Coherence control is demonstrated on the positively charged exciton transition (an electron Coulomb-bound with two holes) in quantum dots embedded in a photonic waveguide by manipulating the electron and hole wavefunctions through an applied lateral electric field. With increasing field up to 15 kV cm1^{-1}, the coherence time increases by a factor of two from 1.4\sim1.4 ns to 2.7\sim2.7 ns. Numerical calculations reveal that longer coherence arises from the separation of charge carriers by up to 6\sim6 nm, which leads to a 30%30\% weaker transition dipole moment. The ability to electrostatically control the coherence time and transition dipole moment opens new avenues for quantum communication and novel coupling schemes between distant qubits.

Keywords

Cite

@article{arxiv.1510.05586,
  title  = {Electronic Coherence Control in a Charged Quantum Dot},
  author = {Galan Moody and Corey McDonald and Ari Feldman and Todd Harvey and Richard P. Mirin and Kevin L. Silverman},
  journal= {arXiv preprint arXiv:1510.05586},
  year   = {2016}
}

Comments

12 pages, 3 figures

R2 v1 2026-06-22T11:23:52.491Z