Your search keyword '"Wasiluk, Maja"' showing total 3 results

1. High-throughput quantum photonic devices emitting indistinguishable photons in the telecom C-band.

Author

Holewa, Paweł, Vajner, Daniel A., Zięba-Ostój, Emilia, Wasiluk, Maja, Gaál, Benedek, Sakanas, Aurimas, Burakowski, Marek, Mrowiński, Paweł, Krajnik, Bartosz, Xiong, Meng, Yvind, Kresten, Gregersen, Niels, Musiał, Anna, Huck, Alexander, Heindel, Tobias, Syperek, Marcin, and Semenova, Elizaveta

Subjects

SINGLE photon generation, TELECOMMUNICATION, QUANTUM communication, BRAGG gratings, PHOTONS, SEMICONDUCTOR quantum dots, PHOTONIC crystals

Abstract

Single indistinguishable photons at telecom C-band wavelengths are essential for quantum networks and the future quantum internet. However, high-throughput technology for single-photon generation at 1550 nm remained a missing building block to overcome present limitations in quantum communication and information technologies. Here, we demonstrate the high-throughput fabrication of quantum-photonic integrated devices operating at C-band wavelengths based on epitaxial semiconductor quantum dots. Our technique enables the deterministic integration of single pre-selected quantum emitters into microcavities based on circular Bragg gratings. Respective devices feature the triggered generation of single photons with ultra-high purity and record-high photon indistinguishability. Further improvements in yield and coherence properties will pave the way for implementing single-photon non-linear devices and advanced quantum networks at telecom wavelengths. An efficient way of realising a large number of telecom single-photon emitters for quantum communication is still missing. Here, the authors use a wide-field imaging technique for fast localization of single InAs/InP quantum dots, which are then integrated into circular Bragg grating cavities featuring high single-photon purity and indistinguishability. [ABSTRACT FROM AUTHOR]

Published

2024

2. Distributed Bragg Reflector–Mediated Excitation of InAs/InP Quantum Dots Emitting in the Telecom C‐Band.

Author

Musiał, Anna, Wasiluk, Maja, Gawełczyk, Michał, Reithmaier, Johann Peter, Benyoucef, Mohamed, Sęk, Grzegorz, and Rudno-Rudziński, Wojciech

Subjects

QUANTUM dots, TELECOMMUNICATION, EXCITATION spectrum, LOW temperatures, CHARGE carriers, PHOTONS, PHOTOLUMINESCENCE, MASS transfer

Abstract

Herein, it is demonstrated that optical excitation of InAs quantum dots (QDs) embedded directly in an InP matrix can be mediated via states in a quaternary compound constituting an InP/InGaAlAs bottom distributed Bragg reflector (DBR) and native defects in the InP matrix. It does not only change the carrier relaxation in the structure but could also lead to the imbalanced occupation of QDs with charge carriers, because the band structure favors the transfer of holes. Thermal activation of carrier transfer can be observed as an increase in the emission intensity versus temperature for excitation powers below saturation on the level of both an inhomogeneously broadened QD ensemble and single QD transitions. That increase in the QD emission is accompanied by a decrease in the emission from the InGaAlAs layer at low temperatures. Finally, carrier transfer between the InGaAlAs layer of the DBR and the InAs/InP QDs is directly proven by the photoluminescence excitation spectrum of the QD ensemble. The reported carrier transfer can increase the relaxation time of carriers into the QDs and thus be detrimental to the coherence properties of single and entangled photons. It is important to take it into account while designing QD‐based devices. [ABSTRACT FROM AUTHOR]

Published

2023

3. Optical Quality of InAs/InP Quantum Dots on Distributed Bragg Reflector Emitting at 3rd Telecom Window Grown by Molecular Beam Epitaxy.

Author

Smołka, Tristan, Posmyk, Katarzyna, Wasiluk, Maja, Wyborski, Paweł, Gawełczyk, Michał, Mrowiński, Paweł, Mikulicz, Monika, Zielińska, Agata, Reithmaier, Johann Peter, Musiał, Anna, and Benyoucef, Mohamed

Subjects

QUANTUM dots, MOLECULAR beam epitaxy, DISTRIBUTED Bragg reflectors, PHOTON counting, TELECOMMUNICATION, QUANTUM efficiency, PHOTONS

Abstract

We present an experimental study on the optical quality of InAs/InP quantum dots (QDs). Investigated structures have application relevance due to emission in the 3rd telecommunication window. The nanostructures are grown by ripening-assisted molecular beam epitaxy. This leads to their unique properties, i.e., low spatial density and in-plane shape symmetry. These are advantageous for non-classical light generation for quantum technologies applications. As a measure of the internal quantum efficiency, the discrepancy between calculated and experimentally determined photon extraction efficiency is used. The investigated nanostructures exhibit close to ideal emission efficiency proving their high structural quality. The thermal stability of emission is investigated by means of microphotoluminescence. This allows to determine the maximal operation temperature of the device and reveal the main emission quenching channels. Emission quenching is predominantly caused by the transition of holes and electrons to higher QD's levels. Additionally, these carriers could further leave the confinement potential via the dense ladder of QD states. Single QD emission is observed up to temperatures of about 100 K, comparable to the best results obtained for epitaxial QDs in this spectral range. The fundamental limit for the emission rate is the excitation radiative lifetime, which spreads from below 0.5 to almost 1.9 ns (GHz operation) without any clear spectral dispersion. Furthermore, carrier dynamics is also determined using time-correlated single-photon counting. [ABSTRACT FROM AUTHOR]

Published

2021