Issue 45, 2019

InAs quantum dot in a needlelike tapered InP nanowire: a telecom band single photon source monolithically grown on silicon

Abstract

Realizing single photon sources emitting in the telecom band on silicon substrates is essential to reach complementary-metal–oxide–semiconductor (CMOS) compatible devices that secure communications over long distances. In this work, we propose the monolithic growth of needlelike tapered InAs/InP quantum dot-nanowires (QD-NWs) on silicon substrates with a small taper angle and a nanowire diameter tailored to support a single mode waveguide. Such a NW geometry is obtained by a controlled balance over axial and radial growths during the gold-catalyzed growth of the NWs by molecular beam epitaxy. This allows us to investigate the impact of the taper angle on the emission properties of a single InAs/InP QD-NW. At room temperature, a Gaussian far-field emission profile in the telecom O-band with a beam divergence angle θ = 30° is demonstrated using a single InAs QD embedded in a 2° tapered InP NW. Moreover, single photon emission is observed at cryogenic temperature for an off-resonant excitation and the best result, g2(0) = 0.05, is obtained for a 7° tapered NW. This all-encompassing study paves the way for the monolithic growth on silicon of an efficient single photon source in the telecom band based on InAs/InP QD-NWs.

Graphical abstract: InAs quantum dot in a needlelike tapered InP nanowire: a telecom band single photon source monolithically grown on silicon

Supplementary files

Article information

Article type
Paper
Submitted
18 Jul 2019
Accepted
13 Oct 2019
First published
14 Oct 2019

Nanoscale, 2019,11, 21847-21855

InAs quantum dot in a needlelike tapered InP nanowire: a telecom band single photon source monolithically grown on silicon

A. Jaffal, W. Redjem, P. Regreny, H. S. Nguyen, S. Cueff, X. Letartre, G. Patriarche, E. Rousseau, G. Cassabois, M. Gendry and N. Chauvin, Nanoscale, 2019, 11, 21847 DOI: 10.1039/C9NR06114B

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