A serious concern with quantum key distribution (QKD) schemes is that, when under attack, the quantum devices in a real-life implementation may behave differently than modeled in the security proof. This can lead to real-life attacks against provably secure QKD schemes. In this work, we show that the standard BB84 QKD scheme is one-sided device-independent. This means that security holds even if Bob’s quantum device is arbitrarily malicious, as long as Alice’s device behaves as it should. Thus, we can completely remove the trust into Bob’s quantum device for free, without the need for changing the scheme, and without the need for hard-to-implement loophole-free violations of Bell inequality, as is required for fully (meaning two-sided) device-independent QKD. For our analysis, we introduce a new quantum game, called a monogamy-of-entanglement game, and we show a strong parallel repetition theorem for this game. This new notion is likely to be of independent interest and to find additional applications. Indeed, besides the application to QKD, we also show a direct application to position-based quantum cryptography: we give the first security proof for a one-round position-verification scheme that requires only single-qubit operations.
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Springer
T. Johansson , P.Q. Nguyen
Quantum Cryptography
Annual International Conference on the Theory and Applications of Cryptographic Techniques
Cryptology

Tomamichel, M., Fehr, S., Kaniewski, J., & Wehner, S. (2013). One-Sided Device Independent QKD and Position-Based Cryptography from Monogamy Games. In T. Johansson & P. Q. Nguyen (Eds.), Proceedings of Annual International Conference on the Theory and Applications of Cryptographic Techniques 2013 (EUROCRYPT 2013) (pp. 609–625). Springer.