Provably secure key establishment against quantum adversaries
Abstract
At Crypto 2011, some of us had proposed a family of cryptographic protocols for key establishment capable of protecting quantum and classical legitimate parties unconditionally against a quantum eavesdropper in the query complexity model. Unfortunately, our security proofs were unsatisfactory from a cryptographically meaningful perspective because they were sound only in a worst-case scenario. Here, we extend our results and prove that for any e > 0, there is a classical protocol that allows the legitimate parties to establish a common key after O(N) expected queries to a random oracle, yet any quantum eavesdropper will have a vanishing probability of learning their key after O(N^{1.5-e}) queries to the same oracle. The vanishing probability applies to a typical run of the protocol. If we allow the legitimate parties to use a quantum computer as well, their advantage over the quantum eavesdropper becomes arbitrarily close to the quadratic advantage that classical legitimate parties enjoyed over classical eavesdroppers in the seminal 1974 work of Ralph Merkle. Along the way, we develop new tools to give lower bounds on the number of quantum queries required to distinguish two probability distributions. This method in itself could have multiple applications in cryptography. We use it here to study average-case quantum query complexity, for which we develop a new composition theorem of independent interest.
Cite
@article{arxiv.1704.08182,
title = {Provably secure key establishment against quantum adversaries},
author = {Aleksandrs Belovs and Gilles Brassard and Peter Hoyer and Marc Kaplan and Sophie Laplante and Louis Salvail},
journal= {arXiv preprint arXiv:1704.08182},
year = {2021}
}
Comments
22 pages, no figures, fixes a problem with arXiv:1108.2316v2. Will appear in the Proceedings of the 12th Conference on Theory of Quantum Computation, Communication and Cryptography (TQC), Paris, June 2017. The only change in v2 is that there was a problem with the affiliations in v1