Experimental realization of quantum non-Markovianity through the convex mixing of Pauli semigroups on an NMR quantum processor

• URL: http://arxiv.org/abs/2307.02899v2
• Date: Fri, 26 Apr 2024 13:10:32 GMT
• Title: Experimental realization of quantum non-Markovianity through the convex mixing of Pauli semigroups on an NMR quantum processor
• Authors: Vaishali Gulati, Vinayak Jagadish, R. Srikanth, Kavita Dorai,
• Abstract summary: We consider the cases of equal as well as unequal mixing of two Pauli semigroups, and demonstrate that the resulting map is always non-Markovian. We also study three cases of three-way mixing of the three Pauli semigroups and determine the Markovianity or non-Markovianity of the resulting maps.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: This experimental study aims to investigate the convex combinations of Pauli semigroups with arbitrary mixing parameters to determine whether the resulting dynamical map exhibits Markovian or non-Markovian behavior. Specifically, we consider the cases of equal as well as unequal mixing of two Pauli semigroups, and demonstrate that the resulting map is always non-Markovian. Additionally, we study three cases of three-way mixing of the three Pauli semigroups and determine the Markovianity or non-Markovianity of the resulting maps by experimentally determining the decay rates. To simulate the non-unitary dynamics of a single qubit system with different mixing combinations of Pauli semigroups on an NMR quantum processor, we use an algorithm involving two ancillary qubits. The experimental results align with the theoretical predictions.

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