Controlling the photon number coherence of solid-state quantum light sources for quantum cryptography

Yusuf Karli; Daniel A. Vajner; Florian Kappe; Paul C. A. Hagen; Lena M. Hansen; René Schwarz; T. K. Bracht; Christian Schimpf; Saimon Covre da Silva; Philip Walther; Armando Rastelli; V. M. Axt; Juan C. Loredo; Vikas Remesh; Tobias Heindel; D. E. Reiter; Gregor Weihs

doi:10.1038/s41534-024-00811-2

Controlling the photon number coherence of solid-state quantum light sources for quantum cryptography

Yusuf Karli, Daniel A. Vajner, Florian Kappe, Paul C. A. Hagen, Lena M. Hansen, René Schwarz, T. K. Bracht, Christian Schimpf, Saimon Covre da Silva, Philip Walther, Armando Rastelli, V. M. Axt, Juan C. Loredo, Vikas Remesh, Tobias Heindel, D. E. Reiter, Gregor Weihs

Research output: Contribution to journal › Article › peer-review

Abstract

Quantum communication networks rely on quantum cryptographic protocols including quantum key distribution (QKD) based on single photons. A critical element regarding the security of QKD protocols is the photon number coherence (PNC), i.e., the phase relation between the vacuum and one-photon Fock state. To obtain single photons with the desired properties for QKD protocols, optimal excitation schemes for quantum emitters need to be selected. As emitters, we consider semiconductor quantum dots, that are known to generate on-demand single photons with high purity and indistinguishability. Exploiting two-photon excitation of a quantum dot combined with a stimulation pulse, we demonstrate the generation of high-quality single photons with a controllable degree of PNC. The main tuning knob is the pulse area giving full control from minimal to maximal PNC, while without the stimulating pulse the PNC is negligible in our setup for all pulse areas. Our approach provides a viable route toward secure communication in quantum networks.

Original language	English
Article number	17
Number of pages	17
Journal	npj Quantum Information
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41534-024-00811-2
Publication status	Published - 2024

Fields of science

103 Physics, Astronomy

JKU Focus areas

Digital Transformation

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Karli, Y., Vajner, D. A., Kappe, F., Hagen, P. C. A., Hansen, L. M., Schwarz, R., Bracht, T. K., Schimpf, C., Covre da Silva, S., Walther, P., Rastelli, A., Axt, V. M., Loredo, J. C., Remesh, V., Heindel, T., Reiter, D. E., & Weihs, G. (2024). Controlling the photon number coherence of solid-state quantum light sources for quantum cryptography. npj Quantum Information, 10(1), Article 17. https://doi.org/10.1038/s41534-024-00811-2

@article{37552ff7daa74774901246b422895203,

title = "Controlling the photon number coherence of solid-state quantum light sources for quantum cryptography",

abstract = "Quantum communication networks rely on quantum cryptographic protocols including quantum key distribution (QKD) based on single photons. A critical element regarding the security of QKD protocols is the photon number coherence (PNC), i.e., the phase relation between the vacuum and one-photon Fock state. To obtain single photons with the desired properties for QKD protocols, optimal excitation schemes for quantum emitters need to be selected. As emitters, we consider semiconductor quantum dots, that are known to generate on-demand single photons with high purity and indistinguishability. Exploiting two-photon excitation of a quantum dot combined with a stimulation pulse, we demonstrate the generation of high-quality single photons with a controllable degree of PNC. The main tuning knob is the pulse area giving full control from minimal to maximal PNC, while without the stimulating pulse the PNC is negligible in our setup for all pulse areas. Our approach provides a viable route toward secure communication in quantum networks.",

author = "Yusuf Karli and Vajner, \{Daniel A.\} and Florian Kappe and Hagen, \{Paul C. A.\} and Hansen, \{Lena M.\} and Ren{\'e} Schwarz and Bracht, \{T. K.\} and Christian Schimpf and \{Covre da Silva\}, Saimon and Philip Walther and Armando Rastelli and Axt, \{V. M.\} and Loredo, \{Juan C.\} and Vikas Remesh and Tobias Heindel and Reiter, \{D. E.\} and Gregor Weihs",

year = "2024",

doi = "10.1038/s41534-024-00811-2",

language = "English",

volume = "10",

journal = "npj Quantum Information",

issn = "2056-6387",

number = "1",

}

Karli, Y, Vajner, DA, Kappe, F, Hagen, PCA, Hansen, LM, Schwarz, R, Bracht, TK, Schimpf, C, Covre da Silva, S, Walther, P, Rastelli, A, Axt, VM, Loredo, JC, Remesh, V, Heindel, T, Reiter, DE & Weihs, G 2024, 'Controlling the photon number coherence of solid-state quantum light sources for quantum cryptography', npj Quantum Information, vol. 10, no. 1, 17. https://doi.org/10.1038/s41534-024-00811-2

TY - JOUR

T1 - Controlling the photon number coherence of solid-state quantum light sources for quantum cryptography

AU - Karli, Yusuf

AU - Vajner, Daniel A.

AU - Kappe, Florian

AU - Hagen, Paul C. A.

AU - Hansen, Lena M.

AU - Schwarz, René

AU - Bracht, T. K.

AU - Schimpf, Christian

AU - Covre da Silva, Saimon

AU - Walther, Philip

AU - Rastelli, Armando

AU - Axt, V. M.

AU - Loredo, Juan C.

AU - Remesh, Vikas

AU - Heindel, Tobias

AU - Reiter, D. E.

AU - Weihs, Gregor

PY - 2024

Y1 - 2024

N2 - Quantum communication networks rely on quantum cryptographic protocols including quantum key distribution (QKD) based on single photons. A critical element regarding the security of QKD protocols is the photon number coherence (PNC), i.e., the phase relation between the vacuum and one-photon Fock state. To obtain single photons with the desired properties for QKD protocols, optimal excitation schemes for quantum emitters need to be selected. As emitters, we consider semiconductor quantum dots, that are known to generate on-demand single photons with high purity and indistinguishability. Exploiting two-photon excitation of a quantum dot combined with a stimulation pulse, we demonstrate the generation of high-quality single photons with a controllable degree of PNC. The main tuning knob is the pulse area giving full control from minimal to maximal PNC, while without the stimulating pulse the PNC is negligible in our setup for all pulse areas. Our approach provides a viable route toward secure communication in quantum networks.

AB - Quantum communication networks rely on quantum cryptographic protocols including quantum key distribution (QKD) based on single photons. A critical element regarding the security of QKD protocols is the photon number coherence (PNC), i.e., the phase relation between the vacuum and one-photon Fock state. To obtain single photons with the desired properties for QKD protocols, optimal excitation schemes for quantum emitters need to be selected. As emitters, we consider semiconductor quantum dots, that are known to generate on-demand single photons with high purity and indistinguishability. Exploiting two-photon excitation of a quantum dot combined with a stimulation pulse, we demonstrate the generation of high-quality single photons with a controllable degree of PNC. The main tuning knob is the pulse area giving full control from minimal to maximal PNC, while without the stimulating pulse the PNC is negligible in our setup for all pulse areas. Our approach provides a viable route toward secure communication in quantum networks.

UR - https://www.nature.com/articles/s41534-024-00811-2

UR - https://www.scopus.com/pages/publications/85183313110

U2 - 10.1038/s41534-024-00811-2

DO - 10.1038/s41534-024-00811-2

M3 - Article

SN - 2056-6387

VL - 10

JO - npj Quantum Information

JF - npj Quantum Information

IS - 1

M1 - 17

ER -

Controlling the photon number coherence of solid-state quantum light sources for quantum cryptography

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