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Beating the Fault-Tolerance Bound and Security Loopholes for Byzantine Agreement with a Quantum Solution

Chen-Xun Weng, Ruiqi Gao, Yu Bao, Bing-Hong Li, Wen‐Bo Liu, Yuan-Mei Xie, Yu-Shuo Lu, Hua‐Lei Yin, Zeng‐Bing Chen

2023Research33 citationsDOIOpen Access PDF

Abstract

Byzantine agreement, the underlying core of blockchain, aims to make every node in a decentralized network reach consensus. Classical Byzantine agreements unavoidably face two major problems. One is 1/3 fault-tolerance bound, which means that the system to tolerate f malicious players requires at least 3 f + 1 players. The other is the security loopholes from its classical cryptography methods. Here, we propose a Byzantine agreement framework with unconditional security to break this bound with nearly 1/2 fault tolerance due to multiparty correlation provided by quantum digital signatures. It is intriguing that quantum entanglement is not necessary to break the 1/3 fault-tolerance bound, and we show that weaker correlation, such as asymmetric relationship of quantum digital signature, can also work. Our work strictly obeys two Byzantine conditions and can be extended to any number of players without requirements for multiparticle entanglement. We experimentally demonstrate three-party and five-party consensus for a digital ledger. Our work indicates the quantum advantage in terms of consensus problems and suggests an important avenue for quantum blockchain and quantum consensus networks.

Topics & Concepts

Byzantine fault toleranceQuantum entanglementComputer scienceQuantumUpper and lower boundsNode (physics)Fault toleranceQuantum computerTheoretical computer scienceMathematicsPhysicsDistributed computingQuantum mechanicsMathematical analysisBlockchain Technology Applications and SecurityDistributed systems and fault toleranceRandom Matrices and Applications
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