31/03/2006, 15:00 — 16:00 — Room P4.35, Mathematics Building
Christopher Fuchs, Bell Laboratories
Maximally Sensitive Quantum States and a Measure of Quantumness
In quantum Shannon theory, the calculational task for any given quantum channel is to find a set of quantum states that are maximally resistant to distortion by the channel. In quantum cryptography, however, one welcomes the circumstance that quantum states are sensitive to their environments; for it is a feature that can be used to detect eavesdropping. When an eavesdropper gathers information on the identity of one of a set of nonorthogonal states, she necessarily causes a disturbance to those states. This situation calls for a means to quantify how sensitive to eavesdropping one alphabet of quantum states is over another. We explore one such measure, and use it to define a set of maximally sensitive quantum states. Sets of such maximally sensitive quantum states have several interesting properties that indicate they may be of wider interest than the problem from which they came.
Supported by: Phys-Info (IT), SQIG (IT), CeFEMA and CAMGSD, with funding from FCT, FEDER and EU FP7, specifically through the Doctoral Programme in the Physics and Mathematics of Information (DP-PMI), FCT strategic projects PEst-OE/EEI/LA0008/2013 and UID/EEA/50008/2013, IT project QuSim, project CRUP-CPU CQVibes, the FP7 Coordination Action QUTE-EUROPE (600788), and the FP7 projects Landauer (GA 318287) and PAPETS (323901).
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