Measurement-Protected Quantum Key Distribution
Abstract
In the distribution of quantum states over a long distance, not only are quantum states corrupted by interactions with an environment but also a measurement setting should be re-aligned such that detection events can be ensured for the resulting states. In this work, we present measurement-protected quantum key distribution where a measurement is protected against the interactions quantum states experience during the transmission, without the verification of a channel. As a result, a receiver does not have to revise the measurement that has been prepared in a noiseless scenario since it would remain ever optimal. The measurement protection is achieved by applications of local unitary transformations before and after the transmission, that leads to a supermap transforming an arbitrary channel to a depolarization one. An experimental demonstration is presented with the polarization encoding on photonic qubits. It is shown that the security bounds for prepare-and-measure protocols can be improved, for instance, errors up to 20.7% can be tolerated in the Bennett-Brassard 1984 protocol.
Cite
@article{arxiv.1912.00768,
title = {Measurement-Protected Quantum Key Distribution},
author = {Spiros Kechrimparis and Heasin Ko and Young-Ho Ko and Kap-Joong Kim and Byung-Seok Choi and Chahan M. Kropf and Chun Ju Youn and Joonwoo Bae},
journal= {arXiv preprint arXiv:1912.00768},
year = {2026}
}
Comments
7 pages, 3 figures