Performance analysis of 
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-dimensional quantum cryptography under state-dependent diffraction

Zhao, Jiapeng; Mirhosseini, Mohammad; Braverman, Boris; Zhou, Yiyu; Rafsanjani, Seyed Mohammad Hashemi; Ren, Yongxiong; Steinhoff, Nicholas K.; Tyler, Glenn A.; Willner, Alan E.; Boyd, Robert W.

doi:10.1103/physreva.100.032319

Cited by 17 publications

(24 citation statements)

References 38 publications

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“…To solve this, one may need to introduce new protocols to mitigate mode-dependent diffraction, for example as discussed in Ref. [35].…”

Section: Free-space Link Across the Ur Campusmentioning

confidence: 99%

“…Since the information is carried by the phase profile, OAM states are vulnerable to atmospheric turbulence. Even though the performance of OAM states in a turbulent channel has been studied both theoretically and experimentally [10,[28][29][30][31][32][33][34][35][36][37][38], realizing high-dimensional OAM-based QKD still remains challenging.To reduce the crosstalk induced by turbulence, most works either rely on post-selection of data or increasing the mode spacing (i.e. not using successive states for encoding) [10,20,33].…”

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confidence: 99%

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Performance of real-time adaptive optics compensation in a turbulent channel with high-dimensional spatial-mode encoding

et al. 2020

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The orbital angular momentum (OAM) of photons is a promising degree of freedom for high-dimensional quantum key distribution (QKD). However, effectively mitigating the adverse effects of atmospheric turbulence is a persistent challenge in OAM QKD systems operating over free-space communication channels. In contrast to previous works focusing on correcting static simulated turbulence, we investigate the performance of OAM QKD in real atmospheric turbulence with real-time adaptive optics (AO) correction. We show that, even our AO system provides a limited correction, it is possible to mitigate the errors induced by weak turbulence and establish a secure channel. The crosstalk induced by turbulence and the performance of AO systems are investigated in two configurations: a lab-scale link with controllable turbulence, and a 340 m long cross-campus link with dynamic atmospheric turbulence. Our experimental results suggest that an advanced AO system with fine beam tracking, reliable beam stabilization, precise wavefront sensing, and accurate wavefront correction is necessary to adequately correct turbulence-induced error. We also propose and demonstrate different solutions to improve the performance of OAM QKD with turbulence, which could enable the possibility of OAM encoding in strong turbulence. IntroductionQuantum key distribution (QKD), which assures unconditionally secure communication between multiple parties, is one of the most promising and encouraging applications of quantum physics [1][2][3]. Instead of relying on mathematical complexity, the security of QKD is guaranteed by fundamental physical laws, which indicate that the encrypted keys will remain secure even against eavesdroppers with unlimited computation power [1-3].Since its birth in 1984 [4], the concepts of QKD have been demonstrated in various platforms, including fiber-based networks [5,6], free-space communication links [7,8], underwater [9,10] and over-marine channels [11,12]. However, in most QKD systems, the information is encoded in the polarization degree of freedom, which is a two-dimensional Hilbert space limiting the information capacity to 1 bit per photon. Even through a single-photon source with a high brightness has been developed [13,14], the two-dimensional QKD systems are still photon-inefficient.As a comparison, high-dimensional QKD systems are more photon-efficient and robust to eavesdropping [15][16][17]. In recent decades, many new protocols involving high-dimensional encoding have emerged. Encoding information with orbital angular momentum (OAM) states, which can span an infinite-dimensional Hilbert space, has been experimentally demonstrated arXiv:2002.08884v1 [eess.SP] 14 Feb 2020 to be advantageous in both high-dimensional quantum cryptography [18][19][20][21][22] and classical communication [23,24]. By definition, an OAM state | carrying units of OAM has intertwined helical wavefronts, where denotes the OAM quantum number and is an integer [25]. While efficient and high-fidelity fibers for high-order spatial modes are und...

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“…To solve this, one may need to introduce new protocols to mitigate mode-dependent diffraction, for example as discussed in Ref. [35].…”

Section: Free-space Link Across the Ur Campusmentioning

confidence: 99%

mentioning

confidence: 99%

Performance of real-time adaptive optics compensation in a turbulent channel with high-dimensional spatial-mode encoding

et al. 2020

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“…The intensity pattern of the transmitted beam can remain recognizable after a 1.6 km free-space link, and thus adaptive optics can be potentially used to mitigate turbulence [3], which can be subject to future study. In a realistic free-space link, in addition to the spatial distortion induced by turbulence which can be corrected by adaptive optics, different LG modes accumulate different amount of Gouy phase which can affect the sorting of superposition modes [10]. The Gouy phase for a LG mode can be written as φ = (2p + | | + 1) arctan(z/z R ), where z R is the Rayleigh range and z is the propagation distance.…”

Section: Implementation Of Qkdmentioning

confidence: 99%

“…The Gouy phase for a LG mode can be written as φ = (2p + | | + 1) arctan(z/z R ), where z R is the Rayleigh range and z is the propagation distance. As proposed in [10], pre-compensation can be used in mode preparation at the transmitter's side to guarantee that the mode-dependent phase is cancelled at the receiver's side. Furthermore, the phase-dependent phase can also be removed at the receiver's side.…”

Section: Implementation Of Qkdmentioning

confidence: 99%

“…Within the past few decades the orbital angular momentum (OAM) modes have received extensive attention [1][2][3][4][5] and are widely applied in various information technologies, including quantum teleportation [6], optical communications [7], and quantum key distribution [8][9][10]. Compared to the intrinsically bounded polarization state space, the OAM modes offer an infinite-dimensional Hilbert space for information encoding and therefore can be used to increase the transmission rate of a communication link.…”

Section: Introductionmentioning

confidence: 99%

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Using all transverse degrees of freedom in quantum communications based on a generic mode sorter

et al. 2019

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The dimension of the state space for information encoding offered by the transverse structure of light is usually limited by the finite size of apertures. The widely used orbital angular momentum (OAM) number of Laguerre-Gaussian (LG) modes in free-space communications cannot achieve the theoretical maximum transmission capacity unless the radial degree of freedom is multiplexed into the protocol. While the methodology to sort the radial quantum number has been developed, the application of radial modes in quantum communications requires an additional ability to efficiently measure the superposition of LG modes in the mutually unbiased basis. Here we develop and implement a generic mode sorter that is capable of sorting the superposition of LG modes through the use of a mode converter. As a consequence, we demonstrate an 8-dimensional quantum key distribution experiment involving all three transverse degrees of freedom: spin, azimuthal, and radial quantum numbers of photons. Our protocol presents an important step towards the goal of reaching the capacity limit of a free-space link and can be useful to other applications that involve spatial modes of photons.

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Performance analysis of inter-satellite round-robin differential-phase-shift quantum key distribution

Wang

Malaney

2022

Quantum Inf Process

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As the vision of global-scale unconditional information security becomes gradually realized, the importance of inter-satellite quantum communications has been rapidly increasing. The recently proposed round-robin differential-phase-shift (RRDPS) quantum key distribution (QKD) protocol has attracted much attention not only due to its potential high error tolerance, but also due to its distinct feature that the information leakage can be bounded without monitoring signal disturbances. Despite many existing implementations over fiber-optic channels, the feasibility of RRDPS QKD over an inter-satellite channel is still unknown. Moreover, despite the current advances in orbital angular momentum (OAM) encoding and temporal mode (TM) encoding, most of the existing studies on RRDPS QKD are restricted to time-bin encoding. In this work, we remedy this situation by exploring the feasibility of performing RRDPS QKD using OAM encoding and TM encoding over an inter-satellite channel. Our results indicate that OAM encoding is preferable to time-bin encoding only under the circumstances where a low dimension and a large receiver aperture are used. However, we find that TM encoding is the best encoding scheme in RRDPS QKD over an inter-satellite channel. In particular, we show that TM encoding not only leads to the best performance and the largest feasible parameter range, but also, for the first time, enables all the theoretically available advantages of an increased dimension to be realized in the context of RRDPS QKD.

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Performance analysis of d -dimensional quantum cryptography under state-dependent diffraction

Cited by 17 publications

References 38 publications

Performance of real-time adaptive optics compensation in a turbulent channel with high-dimensional spatial-mode encoding

Performance of real-time adaptive optics compensation in a turbulent channel with high-dimensional spatial-mode encoding

Using all transverse degrees of freedom in quantum communications based on a generic mode sorter

Performance analysis of inter-satellite round-robin differential-phase-shift quantum key distribution

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