Universal Growth Scheme for Quantum Dots with Low Fine-Structure Splitting at Various Emission Wavelengths

Skiba-Szymanska, J.; Stevenson, R. M.; Varnava, Christiana; Felle, Martin; Huwer, Jan; Müller, Tina; Bennett, A. J.; Lee, James P.; Farrer, I.; Krysa, A. B.; Spencer, Peter; Goff, Lucy E.; Ritchie, D. A.; Heffernan, J.; Shields, A. J.

doi:10.1103/physrevapplied.8.014013

Cited by 63 publications

(85 citation statements)

References 29 publications

(36 reference statements)

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“…Nevertheless, the experiment made use of a conventional QD emitting at short wavelength, suffering from high losses when being transmitted over a long optical fiber and, therefore, not suitable for a scalable architecture. Great effort has been put into the development of QDs emitting at telecommunication wavelengths [21][22][23][24], culminating in independent demonstrations of entangled photon emission [25] and interference with laser photons [26]. Here, we report the implementation of a quantum-relay experiment in the telecommunication O band (close to 1310 nm), suitable for secure quantumcommunication applications and, at the same time, fully compatible with the existing communication infrastructure regarding networks and sources.…”

Section: Introductionmentioning

confidence: 99%

Quantum-Dot-Based Telecommunication-Wavelength Quantum Relay

et al. 2017

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The development of quantum relays for long-haul and attack-proof quantum communication networks operating with weak coherent laser pulses requires entangled photon sources at telecommunication wavelengths with intrinsic single-photon emission for most practical implementations. Using a semiconductor quantum dot emitting entangled photon pairs in the telecommunication O band, we demonstrate a quantum relay fulfilling both of these conditions. The system achieves a maximum fidelity of 94.5% for implementation of a standard four-state protocol with input states generated by a laser. We further investigate robustness against frequency detuning of the narrow-band input and perform process tomography of the teleporter, revealing operation for arbitrary pure input states, with an average gate fidelity of 83.6%. The results highlight the potential of semiconductor light sources for compact and robust quantum-relay technology that is compatible with existing communication infrastructures.

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Section: Introductionmentioning

confidence: 99%

Quantum-Dot-Based Telecommunication-Wavelength Quantum Relay

et al. 2017

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“…MOCVD‐grown structures allowed also for realization of single‐photon emission under electrical carrier injection . However, all of them lead to strongly anisotropic structures with FSS well above 20 µeV therefore limiting their applicability. Recently, another technological approach for realization of InP‐based QDs, namely the droplet epitaxy growth has been reported .…”

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confidence: 99%

High‐Purity Triggered Single‐Photon Emission from Symmetric Single InAs/InP Quantum Dots around the Telecom C‐Band Window

et al. 2019

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The authors demonstrate pure triggered single‐photon emission from quantum dots (QDs) around the telecommunication C‐band window, with characteristics preserved under non‐resonant excitation at saturation, that is, the highest possible, lifetime‐limited emission rates. The direct measurement of emission dynamics reveals photoluminescence decay times in the range of (1.7–1.8) ns corresponding to maximal photon generation rates exceeding 0.5 GHz. The measurements of the second‐order correlation function exhibit, for the best case, a lack of coincidences at zero time delay—no multiple photon events are registered within the experimental accuracy. This is achieved by exploiting a new class of low‐density and in‐plane symmetric InAs/InP QDs grown by molecular beam epitaxy on a distributed Bragg reflector, perfectly suitable for non‐classical light generation for quantum optics experiments and quantum‐secured fiber‐based optical communication schemes.

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“…In addition to the SK growth, droplet epitaxy and droplet etching methods have been established which result in strain‐free QDs. Here, demonstrated material combinations are GaAs/AlGaAs QDs emitting at 780 nm, InAs/GaAs QDs emitting around 900 nm, and InAs/InP QDs emitting at 1550 nm . Also, pyramidal QDs grown in tetrahedral recesses etched in GaAs have recently demonstrated strong potential for scalable non‐classical light sources .…”

Section: Fundamentalsmentioning

confidence: 99%

Generation of Non‐Classical Light Using Semiconductor Quantum Dots

et al. 2019

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Sources of non‐classical light are of paramount importance for future applications in quantum science and technology such as quantum communication, quantum computation and simulation, quantum sensing, and quantum metrology. This Review is focused on the fundamentals and recent progress in the generation of single photons, entangled photon pairs, and photonic cluster states using semiconductor quantum dots. Specific fundamentals which are discussed are a detailed quantum description of light, properties of semiconductor quantum dots, and light–matter interactions. This includes a framework for the dynamic modeling of non‐classical light generation and two‐photon interference. Recent progress is discussed in the generation of non‐classical light for off‐chip applications as well as implementations for scalable on‐chip integration.

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Universal Growth Scheme for Quantum Dots with Low Fine-Structure Splitting at Various Emission Wavelengths

Cited by 63 publications

References 29 publications

Quantum-Dot-Based Telecommunication-Wavelength Quantum Relay

Quantum-Dot-Based Telecommunication-Wavelength Quantum Relay

High‐Purity Triggered Single‐Photon Emission from Symmetric Single InAs/InP Quantum Dots around the Telecom C‐Band Window

Generation of Non‐Classical Light Using Semiconductor Quantum Dots

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