We study quantum communication in the presence of adversarial noise. In this setting, communicating with perfect fidelity requires using a quantum code of bounded minimum distance, for which the best known rates are given by the quantum Gilbert-Varshamov (QGV) bound. By asking only for arbitrarily high fidelity and allowing the sender and reciever to use a secret key with length logarithmic in the number of qubits sent, we achieve a dramatic improvement over the QGV rates. In fact, we find protocols that achieve arbitrarily high fidelity at noise levels for which perfect fidelity is impossible. To achieve such communication rates, we introduce fully quantum list codes, which may be of independent interest
We present the scheme of compatible quantum information analysis of the quantum key distribution (QK...
It was shown in [WST08] that cryptographic primitives can be implemented based on the assumption th...
Ahlswede R, Bjelakovic I, Boche H, Nötzel J. Quantum Capacity under Adversarial Quantum Noise: Arbit...
In this correspondence, we study quantum communication in the presence of adversarial noise. In this...
This thesis provides bounds on the performance of quantum error correcting codes when used for quant...
We consider the problem of implementing two-party interactive quantum communication over noisy chann...
We revisit a fundamental open problem in quantum information theory, namely, whether it is possible ...
We revisit a fundamental open problem in quantum information theory, namely whether it is possible t...
© 2018 Copyright held by the owner/author(s). We consider the problem of implementing two-party inte...
When the 4-state or the 6-state protocol of quantum cryptography is carried out on a noisy (i.e. rea...
In this work our aim has been to elucidate our theoretical developments that bolster the efficiency ...
An upper limit is given to the amount of quantum information that can be transmitted reliably down a...
A secret key shared through quantum key distribution between two cooperative players is secure again...
We provide a general formalism to characterize the cryptographic properties of quantum channels in t...
We consider the problem of implementing two-party interactive quantum communication over noisy chann...
We present the scheme of compatible quantum information analysis of the quantum key distribution (QK...
It was shown in [WST08] that cryptographic primitives can be implemented based on the assumption th...
Ahlswede R, Bjelakovic I, Boche H, Nötzel J. Quantum Capacity under Adversarial Quantum Noise: Arbit...
In this correspondence, we study quantum communication in the presence of adversarial noise. In this...
This thesis provides bounds on the performance of quantum error correcting codes when used for quant...
We consider the problem of implementing two-party interactive quantum communication over noisy chann...
We revisit a fundamental open problem in quantum information theory, namely, whether it is possible ...
We revisit a fundamental open problem in quantum information theory, namely whether it is possible t...
© 2018 Copyright held by the owner/author(s). We consider the problem of implementing two-party inte...
When the 4-state or the 6-state protocol of quantum cryptography is carried out on a noisy (i.e. rea...
In this work our aim has been to elucidate our theoretical developments that bolster the efficiency ...
An upper limit is given to the amount of quantum information that can be transmitted reliably down a...
A secret key shared through quantum key distribution between two cooperative players is secure again...
We provide a general formalism to characterize the cryptographic properties of quantum channels in t...
We consider the problem of implementing two-party interactive quantum communication over noisy chann...
We present the scheme of compatible quantum information analysis of the quantum key distribution (QK...
It was shown in [WST08] that cryptographic primitives can be implemented based on the assumption th...
Ahlswede R, Bjelakovic I, Boche H, Nötzel J. Quantum Capacity under Adversarial Quantum Noise: Arbit...