Q 16: Quantum Information and Simulation
Monday, March 5, 2018, 14:00–15:45, K 1.020
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14:00 |
Q 16.1 |
Improving the consistency of a quantum experiment with reinforcement learning — •Sabine Wölk and Hans Jürgen Briegel
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14:15 |
Q 16.2 |
Open quantum generalisation of classical Hopfield neural networks — •Eliana Fiorelli, Pietro Rotondo, Matteo Marcuzzi, Juan P Garrahan, Markus Muller, and Igor Lesanovsky
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14:30 |
Q 16.3 |
Projective simulation memory network for solving toy and complex problems — •Alexey Melnikov, Vedran Dunjko, Hendrik Poulsen Nautrup, and Hans Briegel
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14:45 |
Q 16.4 |
Projective simulation applied to non-Markovian problems — •Lea M. Trenkwalder, Vedran Dunjko, and Hans J. Briegel
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15:00 |
Q 16.5 |
The contribution has been withdrawn.
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15:15 |
Q 16.6 |
Modeling the atomtronic analog of an optical polarizing beam splitter, a half-wave plate, and a quarter-wave plate for phonons of the motional state of two trapped atoms — •Naeimeh Mohseni, Marjan Fani, Jonathan Dowling, and Shahpoor Saeidian
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15:30 |
Q 16.7 |
Holography and criticality in matchgate tensor networks — Alexander Jahn, •Marek Gluza, Fernando Pastawski, and Jens Eisert
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