CMOS Compatible Single Photon Sources based on SiGe Quantum Dots

Provider

Ministry of Education, Youth and Sports

Programme

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Call for proposals

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Main participants

Masarykova univerzita / Přírodovědecká fakulta

Contest type

M2 - International cooperation

Contract ID

MSMT-9964/2018-2/1

Project name in Czech

CMOS Compatible Single Photon Sources based on SiGe Quantum Dots

Annotation in Czech

The efficient generation of quantum states of light is a vital task in Quantum Photonics. Current approaches are bulky and expensive with low generation rates and the few commercial single photon sources are either not compatible with telecoms standards, require cryogenic temperatures or are bulky benchtop devices. CUSPIDOR will develop a novel integrated photonic platform relying on a fully CMOS-compatible technology, which will provide compact and highly efficient sources of deterministic single photons at telecommunications wavelengths. Using quantum electro-dynamics principles, silicon-germanium quantum dots (QDs) in silicon will be optimised for high radiative efficiency at temperatures up to 300K. Ion implantation will be implemented during growth, modifying the electron wave function and improving the radiative recombination rate. Optimal and deterministic coupling of the QDs with high quality-factor resonators will be achieved by site controlled QD growth in combination with precisely aligned, lithographically defined photonic crystal resonators, allowing upscaling and a straight forward implementation of areas of identical single photon sources. Combining these sources with lateral p-i-n diodes will yield electrically triggered single photon emitters. By using the QD to provide a strong optical nonlinearity, a single photon source (SPS) will be realized via the implementation of an on-chip photon blockade. Quantum interference in a photonic molecule increases the system’s sensitivity providing a practical path to the first integrated photon blockade device - i.e a “holy grail” of the Quantum photonics community - and provide opportunities for coherent protocols not possible with a single quantum dot.

R&D category

ZV - Basic research

OECD FORD - main branch

10302 - Condensed matter physics (including formerly solid state physics, supercond.)

OECD FORD - secondary branch

10306 - Optics (including laser optics and quantum optics)

OECD FORD - another secondary branch

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CEP - equivalent branches <br>(according to the <a href="http://www.vyzkum.cz/storage/att/E6EF7938F0E854BAE520AC119FB22E8D/Prevodnik_oboru_Frascati.pdf">converter</a>)

BH - Optics, masers and lasers<br>BM - Solid-state physics and magnetism

Provider evaluation

V - Vynikající výsledky projektu (s mezinárodním významem atd.)

Project results evaluation

During the CUSPIDOR project, effective methods for computation of intersticial SiGe quantum dot electronic structure were developed by MU. These were a method of parameter modification using DFT and the tight binding model. Those were connected to the multiparticle corrections using configuration interaction.

Realization period - beginning

Apr 1, 2018

Realization period - end

Jun 30, 2022

Project status

U - Finished project

Latest support payment

Feb 22, 2021

Confidentiality

S - Úplné a pravdivé údaje o projektu nepodléhají ochraně podle zvláštních právních předpisů

Data delivery code

CEP23-MSM-8C-U

Data delivery date

Jun 28, 2023

Total approved costs

2,218 thou. CZK

Public financial support

2,218 thou. CZK

Other public sources

0 thou. CZK

Non public and foreign sources

0 thou. CZK