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Efficient Quantum Algorithms for GHZ and W States, and Implementation on the IBM Quantum Computer
Diogo Cruz, Romain Fournier, Fabien Gremion, Alix Jeannerot, K. Komagata, Tara Tosic, Jarla Thiesbrummel, C. L. Chan, N. Macris, M. Dupertuis, C. Javerzac-Galy·July 15, 2018·DOI: 10.1002/qute.201900015
PhysicsMathematicsComputer Science
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Abstract
Efficient deterministic algorithms are proposed with logarithmic step complexities for the generation of entangled GHZN and WN states useful for quantum networks, and an implementation on the IBM quantum computer up to N=16 is demonstrated. Improved quality is then investigated using full quantum tomography for low‐N GHZ and W states. This is completed by parity oscillations and histogram distance for large‐N GHZ and W states, respectively. Robust states are built with about twice the number of quantum bits which were previously achieved.