Proof of security of quantum key distribution with two-way classical communications

TL;DR

This paper proves the security of BB84 and six-state quantum key distribution schemes against general attacks using two-way classical communication, showing increased error tolerance and advantages over one-way protocols.

Contribution

It introduces a new security proof for QKD schemes employing two-way classical communication, demonstrating higher error thresholds and the superiority of the six-state scheme over BB84.

Findings

BB84 with two-way communication tolerates up to 18.9% error rate.

Six-state scheme tolerates up to 26.4% error rate.

Two-way entanglement purification enhances security and key rate.

Abstract

Shor and Preskill have provided a simple proof of security of the standard quantum key distribution scheme by Bennett and Brassard (BB84) by demonstrating a connection between key distribution and entanglement purification protocols with one-way communications. Here we provide proofs of security of standard quantum key distribution schemes, BB84 and the six-state scheme, against the most general attack, by using the techniques of *two*-way entanglement purification. We demonstrate clearly the advantage of classical post-processing with two-way classical communications over classical post-processing with only one-way classical communications in QKD. This is done by the explicit construction of a new protocol for (the error correction/detection and privacy amplification of) BB84 that can tolerate a bit error rate of up to 18.9%, which is higher than what any BB84 scheme with only one-way classical communications can possibly tolerate. Moreover, we demonstrate the advantage of the six-state scheme over BB84 by showing that the six-state scheme can strictly tolerate a higher bit error rate than BB84. In particular, our six-state protocol can tolerate a bit error rate of 26.4%, which is higher than the upper bound of 25% bit error rate for any secure BB84 protocol. Consequently, our protocols may allow higher key generation rate and remain secure over longer distances than previous protocols. Our investigation suggests that two-way entanglement purification is a useful tool in the study of advantage distillation, error correction, and privacy amplification protocols.