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Auteurs principaux: Gilboa, Dar, Jain, Siddhartha, Sattath, Or
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2602.22195
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author Gilboa, Dar
Jain, Siddhartha
Sattath, Or
author_facet Gilboa, Dar
Jain, Siddhartha
Sattath, Or
contents Sybil resistance is a key requirement of decentralized consensus protocols. It is achieved by introducing a scarce resource (such as computational power, monetary stake, disk space, etc.), which prevents participants from costlessly creating multiple fake identities and hijacking the protocol. Quantum states are generically uncloneable, which suggests that they may serve naturally as an unconditionally scarce resource. In particular, uncloneability underlies quantum position-based cryptography, which is unachievable classically. We design a consensus protocol that combines classical hybrid consensus protocols with quantum position verification as the Sybil resistance mechanism, providing security in the standard model, and achieving improved energy efficiency compared to hybrid protocols based on Proof-of-Work. Our protocol inherits the benefits of other hybrid protocols, namely the faster confirmation times compared to pure Proof-of-Work protocols, and resilience against the compounding wealth issue that plagues protocols based on Proof-of-Stake Sybil resistance. We additionally propose a spam prevention mechanism for our protocol in the Random Oracle model.
format Preprint
id arxiv_https___arxiv_org_abs_2602_22195
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Hybrid Consensus with Quantum Sybil Resistance
Gilboa, Dar
Jain, Siddhartha
Sattath, Or
Quantum Physics
Distributed, Parallel, and Cluster Computing
Sybil resistance is a key requirement of decentralized consensus protocols. It is achieved by introducing a scarce resource (such as computational power, monetary stake, disk space, etc.), which prevents participants from costlessly creating multiple fake identities and hijacking the protocol. Quantum states are generically uncloneable, which suggests that they may serve naturally as an unconditionally scarce resource. In particular, uncloneability underlies quantum position-based cryptography, which is unachievable classically. We design a consensus protocol that combines classical hybrid consensus protocols with quantum position verification as the Sybil resistance mechanism, providing security in the standard model, and achieving improved energy efficiency compared to hybrid protocols based on Proof-of-Work. Our protocol inherits the benefits of other hybrid protocols, namely the faster confirmation times compared to pure Proof-of-Work protocols, and resilience against the compounding wealth issue that plagues protocols based on Proof-of-Stake Sybil resistance. We additionally propose a spam prevention mechanism for our protocol in the Random Oracle model.
title Hybrid Consensus with Quantum Sybil Resistance
topic Quantum Physics
Distributed, Parallel, and Cluster Computing
url https://arxiv.org/abs/2602.22195