Single-photon Emission from an Acoustically-driven Lateral Light-emitting Diode
Abstract
Single-photon sources are essential building blocks in quantum photonic networks, where quantum-mechanical properties of photons are utilised to achieve quantum technologies such as quantum cryptography and quantum computing. Most conventional solid-state single-photon sources are based on single emitters such as self-assembled quantum dots, which are created at random locations and require spectral filtering. These issues hinder the integration of a single-photon source into a scaleable photonic quantum network for applications such as on-chip photonic quantum processors. In this work, using only regular lithography techniques on a conventional GaAs quantum well, we realise an electrically triggered single-photon source with a GHz repetition rate and without the need for spectral filtering. In this device, a single electron is carried in the potential minimum of a surface acoustic wave (SAW) and is transported to a region of holes to form an exciton. The exciton then decays and creates a single photon in a lifetime of ~ 100ps. This SAW-driven electroluminescence (EL) yields photon antibunching with , which satisfies the common criterion for a single-photon source . Furthermore, we estimate that if a photon detector receives a SAW-driven EL signal within one SAW period, this signal has a 79%-90% chance of being a single photon. This work shows that a single-photon source can be made by combining single-electron transport and a lateral n-i-p junction. This approach makes it possible to create multiple synchronised single-photon sources at chosen positions with photon energy determined by quantum-well thickness. Compared with conventional quantum-dot-based single-photon sources, this device may be more suitable for an on-chip integrated photonic quantum network.
Cite
@article{arxiv.1901.03464,
title = {Single-photon Emission from an Acoustically-driven Lateral Light-emitting Diode},
author = {Tzu-Kan Hsiao and Antonio Rubino and Yousun Chung and Seok-Kyun Son and Hangtian Hou and Jorge Pedrós and Ateeq Nasir and Gabriel Éthier-Majcher and Megan J. Stanley and Richard T. Phillips and Thomas A. Mitchell and Jonathan P. Griffiths and Ian Farrer and David A. Ritchie and Christopher J. B. Ford},
journal= {arXiv preprint arXiv:1901.03464},
year = {2020}
}