01599nas a2200169 4500008004100000245004900041210004900090260001500139520107400154100001901228700002001247700002001267700002501287700002501312700002401337856006801361 2016 eng d00aComputational Security of Quantum Encryption0 aComputational Security of Quantum Encryption c2016/11/103 a
Quantum-mechanical devices have the potential to transform cryptography. Most research in this area has focused either on the information-theoretic advantages of quantum protocols or on the security of classical cryptographic schemes against quantum attacks. In this work, we initiate the study of another relevant topic: the encryption of quantum data in the computational setting. In this direction, we establish quantum versions of several fundamental classical results. First, we develop natural definitions for private-key and public-key encryption schemes for quantum data. We then define notions of semantic security and indistinguishability, and, in analogy with the classical work of Goldwasser and Micali, show that these notions are equivalent. Finally, we construct secure quantum encryption schemes from basic primitives. In particular, we show that quantum-secure one-way functions imply IND-CCA1-secure symmetric-key quantum encryption, and that quantum-secure trapdoor one-way permutations imply semantically-secure public-key quantum encryption.
1 aAlagic, Gorjan1 aBroadbent, Anne1 aFefferman, Bill1 aGagliardoni, Tommaso1 aSchaffner, Christian1 aJules, Michael, St. uhttps://link.springer.com/chapter/10.1007%2F978-3-319-49175-2_3