Related papers: One- and two-qubit gate infidelities due to motional errors in trapped ions and electrons

One- and two-qubit gate infidelities due to motional errors in trapped ions and electrons

URL: http://arxiv.org/abs/2111.01913v2
Date: Thu, 10 Feb 2022 20:26:05 GMT
Title: One- and two-qubit gate infidelities due to motional errors in trapped ions and electrons
Authors: R. Tyler Sutherland and Qian Yu and Kristin M. Beck and Hartmut H\"affner
Abstract summary: We derive analytic formulae that determine the effect of error mechanisms on one- and two-qubit gates in trapped ions and electrons. First, we analyze, and derive expressions for, the effect of driving field inhomogeneities on one-qubit gate fidelities. Second, we derive expressions for two-qubit gate errors, including static motional frequency shifts, trap anharmonicities, heating, and motional dephasing.
Score: 7.6483834331380205
License: http://creativecommons.org/licenses/by/4.0/
Abstract: In this work, we derive analytic formulae that determine the effect of error mechanisms on one- and two-qubit gates in trapped ions and electrons. First, we analyze, and derive expressions for, the effect of driving field inhomogeneities on one-qubit gate fidelities. Second, we derive expressions for two-qubit gate errors, including static motional frequency shifts, trap anharmonicities, field inhomogeneities, heating, and motional dephasing. We show that, for small errors, each of our expressions for infidelity converges to its respective numerical simulation; this shows our formulae are sufficient for determining error budgets for high-fidelity gates, obviating numerical simulations in future projects. All of the derivations are general to any internal qubit state, and any mixed state of the ion crystal's motion that is diagonal in the Fock state basis. Our treatment of static motional frequency shifts, trap anharmonicities, heating, and motional dephasing apply to both laser-based and laser-free gates, while our treatment of field imhomogenieties applies to laser-free systems.

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