Experimental relativistic zero-knowledge proofs
Pouriya Alikhani,
Nicolas Brunner,
Claude Crépeau (),
Sébastien Designolle (),
Raphaël Houlmann,
Weixu Shi,
Nan Yang and
Hugo Zbinden
Additional contact information
Pouriya Alikhani: McGill University
Nicolas Brunner: University of Geneva
Claude Crépeau: McGill University
Sébastien Designolle: University of Geneva
Raphaël Houlmann: University of Geneva
Weixu Shi: University of Geneva
Nan Yang: Concordia University
Hugo Zbinden: University of Geneva
Nature, 2021, vol. 599, issue 7883, 47-50
Abstract:
Abstract Protecting secrets is a key challenge in our contemporary information-based era. In common situations, however, revealing secrets appears unavoidable; for instance, when identifying oneself in a bank to retrieve money. In turn, this may have highly undesirable consequences in the unlikely, yet not unrealistic, case where the bank’s security gets compromised. This naturally raises the question of whether disclosing secrets is fundamentally necessary for identifying oneself, or more generally for proving a statement to be correct. Developments in computer science provide an elegant solution via the concept of zero-knowledge proofs: a prover can convince a verifier of the validity of a certain statement without facilitating the elaboration of a proof at all1. In this work, we report the experimental realization of such a zero-knowledge protocol involving two separated verifier–prover pairs2. Security is enforced via the physical principle of special relativity3, and no computational assumption (such as the existence of one-way functions) is required. Our implementation exclusively relies on off-the-shelf equipment and works at both short (60 m) and long distances (≥400 m) in about one second. This demonstrates the practical potential of multi-prover zero-knowledge protocols, promising for identification tasks and blockchain applications such as cryptocurrencies or smart contracts4.
Date: 2021
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DOI: 10.1038/s41586-021-03998-y
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