Analogy of free-space quantum key distribution using spatial modes of light: scaling up the distance and the dimensionality

Joseph Meyer; Yuval Reches; Georgi Gary Rozenman; Yaron Oz; Haim Suchowski; Ady Arie

doi:10.1364/OL.557649

Analogy of free-space quantum key distribution using spatial modes of light: scaling up the distance and the dimensionality

Joseph Meyer, Yuval Reches, Georgi Gary Rozenman^*, Yaron Oz, Haim Suchowski, Ady Arie

^*Corresponding author for this work

Massachusetts Institute of Technology

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

3 Scopus citations

Abstract

While quantum key distribution (QKD) shows much potential as a solution to the looming threat that quantum computers place on today’s encryption protocols, efficient and robust systems that operate in free space are still limited. In this paper, we present a classical light analogy of QKD using spatial modes of light, which can provide a higher bit per photon rate than the more commonly used polarization state encoding.We start by demonstrating the BB84 protocol indoors, where we achieve a secure key rate of 1.55 bits per sifted photon. Then, using our outdoor environment, we propagate the signal outdoors over a distance of up to 90 m, modeling the real-world challenges of QKD in free-space applications and successfully demonstrating BB84 for dimensions 2 and 4.

Original language	English
Pages (from-to)	3297-3300
Number of pages	4
Journal	Optics Letters
Volume	50
Issue number	10
DOIs	https://doi.org/10.1364/OL.557649
State	Published - 15 May 2025

Funding

Funders
Ministry of Innovation, Science and Technology
Tel Aviv University

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10.1364/OL.557649

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abstract = "While quantum key distribution (QKD) shows much potential as a solution to the looming threat that quantum computers place on today{\textquoteright}s encryption protocols, efficient and robust systems that operate in free space are still limited. In this paper, we present a classical light analogy of QKD using spatial modes of light, which can provide a higher bit per photon rate than the more commonly used polarization state encoding.We start by demonstrating the BB84 protocol indoors, where we achieve a secure key rate of 1.55 bits per sifted photon. Then, using our outdoor environment, we propagate the signal outdoors over a distance of up to 90 m, modeling the real-world challenges of QKD in free-space applications and successfully demonstrating BB84 for dimensions 2 and 4.",

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AU - Suchowski, Haim

AU - Arie, Ady

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AB - While quantum key distribution (QKD) shows much potential as a solution to the looming threat that quantum computers place on today’s encryption protocols, efficient and robust systems that operate in free space are still limited. In this paper, we present a classical light analogy of QKD using spatial modes of light, which can provide a higher bit per photon rate than the more commonly used polarization state encoding.We start by demonstrating the BB84 protocol indoors, where we achieve a secure key rate of 1.55 bits per sifted photon. Then, using our outdoor environment, we propagate the signal outdoors over a distance of up to 90 m, modeling the real-world challenges of QKD in free-space applications and successfully demonstrating BB84 for dimensions 2 and 4.

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Analogy of free-space quantum key distribution using spatial modes of light: scaling up the distance and the dimensionality

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