Laser-seeding Attack in Quantum Key Distribution

Huang, Anqi; Navarrete, Álvaro; Sun, Shi-Hai; Chaiwongkhot, Poompong; Curty, Marcos; Makarov, Vadim

doi:10.1103/physrevapplied.12.064043

Cited by 72 publications

(45 citation statements)

References 82 publications

(124 reference statements)

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“…Light coming from the wrong direction in the normal QKD optical channel can also alter the intended operation of the system. For instance, external laser light can alter the photon sources in QKD devices and has been shown to weaken security either by seeding the source laser so that consecutive pulses are not phase-independent [ 75 ], altering the wavelength to identify the state choice [ 76 , 77 ], increasing the mean photon number [ 23 , 60 , 77 ], or performing laser machining to physically alter the components inside the QKD setup [ 26 , 61 ]. In this paper, we have focused on light entering from unsuspected places, such as ventilation openings.…”

Section: Discussion and Recommendationsmentioning

confidence: 99%

“…However a system using BB84 for long-distance transmission might also be vulnerable to light injection attacks. It has been shown that even a small unexpected increase of the output mean photon number may break the security of decoy-state BB84 and measurement-device-independent QKD protocols [60], which are often used at longer distances. While the known combined photon-number-splitting and cloning attacks [58] require a quantum memory, the difference between the assumed and the actual key rates opens a loophole in the security of the system and must be fixed.…”

Section: Plos Onementioning

confidence: 99%

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Attacking quantum key distribution by light injection via ventilation openings

García‐Escartín¹,

Sajeed²,

Makarov³

2020

PLoS ONE

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Quantum cryptography promises security based on the laws of physics with proofs of security against attackers of unlimited computational power. However, deviations from the original assumptions allow quantum hackers to compromise the system. We present a side channel attack that takes advantage of ventilation holes in optical devices to inject additional photons that can leak information about the secret key. We experimentally demonstrate light injection on an ID Quantique Clavis2 quantum key distribution platform and show that this may help an attacker to learn information about the secret key. We then apply the same technique to a prototype quantum random number generator and show that its output is biased by injected light. This shows that light injection is a potential security risk that should be addressed during the design of quantum information processing devices.

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Section: Discussion and Recommendationsmentioning

confidence: 99%

Section: Plos Onementioning

confidence: 99%

Attacking quantum key distribution by light injection via ventilation openings

García‐Escartín¹,

Sajeed²,

Makarov³

2020

PLoS ONE

Self Cite

View full text Add to dashboard Cite

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“…Our results show that the channel excess noise may be underestimated by Alice and Bob under the effects of decreased optical attenuation. Subsequently, the secret key rate is overestimated by Alice and Bob, which is coincident with the security analysis arXiv:1904.08777v1 [quant-ph] 17 Apr 2019 result of DVQKD under the effects of reduced optical attenuation [35]. Thus, the decrease of optical attenuation may open a security loophole for Eve to successfully hide her attacks, such as the classical non-Gaussian attack, i.e., the interceptresend attack.…”

Section: Introductionmentioning

confidence: 71%

Practical security of continuous-variable quantum key distribution with reduced optical attenuation

Zheng

Huang

et al. 2019

Phys. Rev. A

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In a practical CVQKD system, the optical attenuator can adjust the Gaussian-modulated coherent states and the local oscillator signal to an optimal value for guaranteeing the security of the system and optimizing the performance of the system. However, the performance of the optical attenuator may deteriorate due to the intentional and unintentional damage of the device. In this paper, we investigate the practical security of a CVQKD system with reduced optical attenuation. We find that the secret key rate of the system may be overestimated based on the investigation of parameter estimation under the effects of reduced optical attenuation. This opens a security loophole for Eve to successfully perform an intercept-resend attack in a practical CVQKD system. To close this loophole, we add an optical fuse at Alice's output port and design a scheme to monitor the level of optical attenuation in real time, which can make the secret key rate of the system evaluated precisely. The analysis shows that these countermeasures can effectively resist this potential attack.

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“…In case of four laser setting, the wavelength control using external laser Lee et al (2017) is successfully implemented, which can be circumvented using a circulator to stop Eve from sending strong beam to the sources. Independently, single laser settings are also attacked using laser seeding and injection locking Huang et al (2019) but circulator will work against these attacks as well. Further, encoding devices can also be attacked using Trojan-horse pulses, which back-reflect from various optical elements revealing information of the sender Gisin et al (2006).…”

Section: Tablementioning

confidence: 99%

Optical designs for realization of a set of schemes for quantum cryptography

2021

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Several quantum cryptographic schemes have been proposed and realized experimentally in the past. However, even with an advancement in quantum technology and escalated interest in the designing of direct secure quantum communication schemes there are not many experimental implementations of these cryptographic schemes. In this paper, we have provided a set of optical circuits for such quantum cryptographic schemes, which have not yet been realized experimentally by modifying some of our theoretically proposed secure communication schemes. Specifically, we have proposed optical designs for the implementation of two single photon and one entangled state based controlled quantum dialogue schemes and subsequently reduced our optical designs to yield simpler designs for realizing other secure quantum communication tasks, i.e., controlled deterministic secure quantum communication, quantum dialogue, quantum secure direct communication, quantum key agreement, and quantum key distribution. We have further proposed an optical design for an entanglement swapping based deterministic secure quantum communication and its controlled counterpart. Finally, a brief discussion on security of the schemes, hacking strategies against different optical elements and corresponding countermeasures is also presented.

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Laser-seeding Attack in Quantum Key Distribution

Cited by 72 publications

References 82 publications

Attacking quantum key distribution by light injection via ventilation openings

Attacking quantum key distribution by light injection via ventilation openings

Practical security of continuous-variable quantum key distribution with reduced optical attenuation

Optical designs for realization of a set of schemes for quantum cryptography

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