TY - GEN
T1 - A New World in the Depths of Microcrypt
T2 - 44th Annual International Conference on the Theory and Applications of Cryptographic Techniques, EUROCRYPT 2025
AU - Behera, Amit
AU - Malavolta, Giulio
AU - Morimae, Tomoyuki
AU - Mour, Tamer
AU - Yamakawa, Takashi
N1 - Publisher Copyright:
© International Association for Cryptologic Research 2025.
PY - 2025/1/1
Y1 - 2025/1/1
N2 - While in classical cryptography one-way functions (OWFs) are widely regarded as the “minimal assumption”, the situation in quantum cryptography is less clear. Recent works have put forward two concurrent candidates for the minimal assumption in quantum cryptography: One-way state generators (OWSGs), postulating the existence of a hard search problem with an efficient verification algorithm, and EFI pairs, postulating the existence of a hard distinguishing problem. Two recent papers [Khurana and Tomer STOC’24; Batra and Jain FOCS’24] showed that OWSGs imply EFI pairs, but the reverse direction remained open. In this work, we give strong evidence that the opposite direction does not hold: We show that there is a quantum unitary oracle relative to which EFI pairs exist but OWSGs do not. In fact, we show a slightly stronger statement that holds also for EFI pairs that output classical bits (QEFID pairs). As a consequence, we separate, via our oracle, QEFID pairs and one-way puzzles from OWSGs and several other Microcrypt primitives, including efficiently verifiable one-way puzzles and unclonable state generators. In particular, this solves a problem left open in [Chung, Goldin, and Gray Crypto’24]. Using similar techniques, we also establish a fully black-box separation (which is slightly weaker than an oracle separation) between private-key quantum money schemes and QEFID pairs. One conceptual implication of our work is that the existence of an efficient verification algorithm may lead to qualitatively stronger primitives in quantum cryptography.
AB - While in classical cryptography one-way functions (OWFs) are widely regarded as the “minimal assumption”, the situation in quantum cryptography is less clear. Recent works have put forward two concurrent candidates for the minimal assumption in quantum cryptography: One-way state generators (OWSGs), postulating the existence of a hard search problem with an efficient verification algorithm, and EFI pairs, postulating the existence of a hard distinguishing problem. Two recent papers [Khurana and Tomer STOC’24; Batra and Jain FOCS’24] showed that OWSGs imply EFI pairs, but the reverse direction remained open. In this work, we give strong evidence that the opposite direction does not hold: We show that there is a quantum unitary oracle relative to which EFI pairs exist but OWSGs do not. In fact, we show a slightly stronger statement that holds also for EFI pairs that output classical bits (QEFID pairs). As a consequence, we separate, via our oracle, QEFID pairs and one-way puzzles from OWSGs and several other Microcrypt primitives, including efficiently verifiable one-way puzzles and unclonable state generators. In particular, this solves a problem left open in [Chung, Goldin, and Gray Crypto’24]. Using similar techniques, we also establish a fully black-box separation (which is slightly weaker than an oracle separation) between private-key quantum money schemes and QEFID pairs. One conceptual implication of our work is that the existence of an efficient verification algorithm may lead to qualitatively stronger primitives in quantum cryptography.
UR - http://www.scopus.com/inward/record.url?scp=105004797347&partnerID=8YFLogxK
U2 - 10.1007/978-3-031-91098-2_2
DO - 10.1007/978-3-031-91098-2_2
M3 - Conference contribution
AN - SCOPUS:105004797347
SN - 9783031910975
T3 - Lecture Notes in Computer Science
SP - 23
EP - 52
BT - Advances in Cryptology – EUROCRYPT 2025 - 44th Annual International Conference on the Theory and Applications of Cryptographic Techniques, Proceedings
A2 - Fehr, Serge
A2 - Fouque, Pierre-Alain
PB - Springer Science and Business Media Deutschland GmbH
Y2 - 4 May 2025 through 8 May 2025
ER -