论文信息 - Private Quantum Channels and the Cost of Randomizing Quantum Information

Private Quantum Channels and the Cost of Randomizing Quantum Information

We investigate how a classical private key can be used by two players, connected by an insecure one-way quantum channel, to perform private communication of quantum information. In particular we show that in order to transmit n qubits privately, 2n bits of shared private key are necessary and sufficient. This result may be viewed as the quantum analogue of the classical one-time pad encryption scheme. From the point of view of the eavesdropper, this encryption process can be seen as a randomization of the original state. We thus also obtain strict bounds on the amount of entropy necessary for randomizing n qubits.

Ronald de Wolf | Michele Mosca | Alain Tapp

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