APL Photonics (Mar 2019)

Quantum-dot single-photon source on a CMOS silicon photonic chip integrated using transfer printing

  • Ryota Katsumi,
  • Yasutomo Ota,
  • Alto Osada,
  • Takuto Yamaguchi,
  • Takeyoshi Tajiri,
  • Masahiro Kakuda,
  • Satoshi Iwamoto,
  • Hidefumi Akiyama,
  • Yasuhiko Arakawa

DOI
https://doi.org/10.1063/1.5087263
Journal volume & issue
Vol. 4, no. 3
pp. 036105 – 036105-6

Abstract

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Silicon photonics is a powerful platform for implementing large-scale photonic integrated circuits (PICs) because of its compatibility with mature complementary-metal-oxide-semiconductor (CMOS) technology. Exploiting silicon-based PICs for quantum photonic information processing (or the so-called silicon quantum photonics) provides a promising pathway for large-scale quantum applications. For the development of scalable silicon quantum PICs, a major challenge is integrating on-silicon quantum light sources that deterministically emit single photons. In this regard, the use of epitaxial InAs/GaAs quantum dots (QDs) is a very promising approach because of their capability of deterministic single-photon emission with high purity and indistinguishability. However, the required hybrid integration is inherently difficult and often lacks the compatibility with CMOS processes. Here, we demonstrate a QD single-photon source integrated on a glass-clad silicon photonic waveguide processed by a CMOS foundry. Hybrid integration is performed using transfer printing, which enables us to integrate heterogeneous optical components in a simple pick-and-place manner and thus assemble them after the entire CMOS process is completed. We observe single-photon emission from the integrated QD and its efficient coupling into the silicon waveguide. Our transfer-printing-based approach is fully compatible with CMOS back-end processes and thus will open the possibility for realizing large-scale quantum PICs that leverage CMOS technology.