Optimal control transport of neutral atoms in optical tweezers at finite temperature
- URL: http://arxiv.org/abs/2402.17831v2
- Date: Mon, 26 Aug 2024 08:13:25 GMT
- Title: Optimal control transport of neutral atoms in optical tweezers at finite temperature
- Authors: Alice Pagano, Daniel Jaschke, Werner Weiss, Simone Montangero,
- Abstract summary: Transport of neutral atoms in Rydberg quantum computers is a crucial step of the initial arrangement of the grid.
We study the application of optimal control and the quantum speed limit for the transport of neutral atoms in optical tweezers at finite temperatures.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The transport of neutral atoms in Rydberg quantum computers is a crucial step of the initial arrangement of the grid as well as to the dynamic connectivity, recently successfully demonstrated. We study the application of optimal control and the quantum speed limit for the transport of neutral atoms in optical tweezers at finite temperatures and analyze how laser noise affects transport fidelity. Open-loop optimal control significantly enhances transport fidelity, achieving an improvement up to $89\%$ for the lowest analyzed temperature of $1\,\mu$K for a distance of three micrometers. Furthermore, we simulate how the transport fidelity behaves in release-and-capture measurements, which are realizable in the experiment to estimate transport efficiency and implement closed-loop optimal control.
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