Realization of quantum digital signatures without the requirement of quantum memory.

Robert J Collins,Erika Andersson,Petros Wallden,Vedran Dunjko,Patrick J Clarke,Ross J Donaldson,John Jeffers,Gerald S Buller

doi:10.1103/physrevlett.113.040502

Abstract

Digital signatures are widely used to provide security for electronic communications, for example, in financial transactions and electronic mail. Currently used classical digital signature schemes, however, only offer security relying on unproven computational assumptions. In contrast, quantum digital signatures offer information-theoretic security based on laws of quantum mechanics. Here, security against forging relies on the impossibility of perfectly distinguishing between nonorthogonal quantum states. A serious drawback of previous quantum digital signature schemes is that they require long-term quantum memory, making them impractical at present. We present the first realization of a scheme that does not need quantum memory and which also uses only standard linear optical components and photodetectors. In our realization, the recipients measure the distributed quantum signature states using a new type of quantum measurement, quantum state elimination. This significantly advances quantum digital signatures as a quantum technology with potential for real applications.

Highlights

Digital signatures are widely used to provide security for electronic communications, for example, in financial transactions and electronic mail
Quantum digital signatures offer information-theoretic security based on laws of quantum mechanics
Digital signature schemes relying on quantum mechanics [5,6,7,8] can be made information-theoretically secure, in contrast to currently used classical digital signature schemes

Summary

Introduction

Digital signatures are widely used to provide security for electronic communications, for example, in financial transactions and electronic mail. Sender, Alice, transmits quantum signature states to the recipients, Bob and Charlie. A recipient of a signed message tests that this agrees with the previously distributed quantum signature states, and accepts the message as genuine if there are sufficiently few mismatches for the whole sequence.

Results

Conclusion