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Hard Quantum Extrapolations in Quantum Cryptography

Quantum Physics 2025-04-15 v3

Abstract

Although one-way functions are well-established as the minimal primitive for classical cryptography, a minimal primitive for quantum cryptography is still unclear. Universal extrapolation, first considered by Impagliazzo and Levin (1990), is hard if and only if one-way functions exist. Towards better understanding minimal assumptions for quantum cryptography, we study the quantum analogues of the universal extrapolation task. Specifically, we put forth the classical\rightarrowquantum extrapolation task, where we ask to extrapolate the rest of a bipartite pure state given the first register measured in the computational basis. We then use it as a key component to establish new connections in quantum cryptography: (a) quantum commitments exist if classical\rightarrowquantum extrapolation is hard; and (b) classical\rightarrowquantum extrapolation is hard if any of the following cryptographic primitives exists: quantum public-key cryptography (such as quantum money and signatures) with a classical public key or 2-message quantum key distribution protocols. For future work, we further generalize the extrapolation task and propose a fully quantum analogue. We show that it is hard if quantum commitments exist, and it is easy for quantum polynomial space.

Keywords

Cite

@article{arxiv.2409.16516,
  title  = {Hard Quantum Extrapolations in Quantum Cryptography},
  author = {Luowen Qian and Justin Raizes and Mark Zhandry},
  journal= {arXiv preprint arXiv:2409.16516},
  year   = {2025}
}

Comments

To appear in EUROCRYPT 2025

R2 v1 2026-06-28T18:55:55.450Z