APL Photonics (Oct 2023)

Compact chirped fiber Bragg gratings for single-photon generation from quantum dots

  • Vikas Remesh,
  • Ria G. Krämer,
  • René Schwarz,
  • Florian Kappe,
  • Yusuf Karli,
  • Malte Per Siems,
  • Thomas K. Bracht,
  • Saimon Filipe Covre da Silva,
  • Armando Rastelli,
  • Doris E. Reiter,
  • Daniel Richter,
  • Stefan Nolte,
  • Gregor Weihs

DOI
https://doi.org/10.1063/5.0164222
Journal volume & issue
Vol. 8, no. 10
pp. 101301 – 101301-11

Abstract

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A scalable source of single photons is a key constituent of an efficient quantum photonic architecture. To realize this, it is beneficial to have an ensemble of quantum emitters that can be collectively excited with high efficiency. Semiconductor quantum dots hold great potential in this context due to their excellent photophysical properties. Spectral variability of quantum dots is commonly regarded as a drawback introduced by the fabrication method. However, this is beneficial to realize a frequency-multiplexed single-photon platform. Chirped pulse excitation, relying on the so-called adiabatic rapid passage, is the most efficient scheme to excite a quantum dot ensemble due to its immunity to individual quantum dot parameters. Yet, the existing methods of generating chirped laser pulses to excite a quantum emitter are bulky, lossy, and mechanically unstable, which severely hampers the prospects of a quantum dot photon source. Here, we present a compact, robust, and high-efficiency alternative for chirped pulse excitation of solid-state quantum emitters. Our simple plug-and-play module consists of chirped fiber Bragg gratings, fabricated via femtosecond inscription, to provide high values of dispersion in the near-infrared spectral range, where the quantum dots emit. We characterize and benchmark the performance of our method via chirped excitation of a GaAs quantum dot, establishing high-fidelity single-photon generation. Our highly versatile chirping module coupled to a photon source is a significant milestone toward realizing practical quantum photonic devices.