Q 44: Quantum Information (Concepts and Methods) III
Thursday, March 14, 2019, 10:30–12:30, S HS 001 Chemie
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10:30 |
Q 44.1 |
States that can be reached with hybrid algorithms — •Joachim Welz, Filip Wudarski, and Andreas Buchleitner
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10:45 |
Q 44.2 |
Quantum walk driven by entangled coins — •Shahram Panahiyan and Stephan Fritzsche
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11:00 |
Q 44.3 |
Eigenvalue Measurement of Topologically Protected Edge states in Split-Step Quantum Walks — •Thomas Nitsche, Tobias Geib, Christoph Stahl, Lennart Lorz, Christopher Cedzich, Sonja Barkhofen, Reinhard F. Werner, and Christine Silberhorn
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11:15 |
Q 44.4 |
Bound entangled states fit for robust experimental verification — •Gael Sentís, Johannes N. Greiner, Jiangwei Shang, Jens Siewert, and Matthias Kleinmann
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11:30 |
Q 44.5 |
Experimental implementation of a device-independent dimension test using genuine temporal correlations — •Hendrik Siebeneich, Cornelia Spee, Timm Florian Gloger, Peter Kaufmann, Michael Johanning, Matthias Kleinmann, Otfried Gühne, and Christoph Wunderlich
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11:45 |
Q 44.6 |
Blind calibration quantum state tomography — •Jadwiga Wilkens, Ingo Roth, Dominik Hangleiter, and Jens Eisert
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12:00 |
Q 44.7 |
Sample complexity of device-independently certified ``quantum supremacy — •Dominik Hangleiter, Martin Kliesch, Jens Eisert, and Christian Gogolin
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12:15 |
Q 44.8 |
Distinguishing between statistical and systematic errors in quantum process tomography — •Sabine Wölk, Theeraphot Sriarunothai, Gouri Giri, and Christof Wunderlich
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