Related papers: Rapid passage to ordered states in Rydberg atom arrays

Rapid passage to ordered states in Rydberg atom arrays

URL: http://arxiv.org/abs/2504.19214v1
Date: Sun, 27 Apr 2025 12:33:54 GMT
Title: Rapid passage to ordered states in Rydberg atom arrays
Authors: Liang Zeng, Fei Zhu, Li Chen, Heng Shen,
Abstract summary: We develop a rapid passage to ordered many-body states in a Rydberg atomic chain.<n>We experimentally validate the NQN scheme on the neutral-atom quantum cloud computer Aquila.
Score: 14.300711995373826
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Given a finite lifetime, a ubiquitous challenge in quantum systems is how to prepare a target state in the shortest possible time. This issue is particularly relevant for Rydberg atom arrays in optical tweezers where the dephasing time is typically restricted to a few microseconds. In this work, we develop a rapid passage to ordered many-body states in a Rydberg atomic chain, which allows the transition of the system to various ordered phases in the phase diagram, such as the Z$_2$-, Z$_3$-, and Z$_4$-ordered antiferromagnetic states. Our scheme ramps the parameter in a "non-adiabatic to quasi-adiabatic to non-adiabatic (NQN)" manner. The NQN configuration significantly reduces the time cost required for the state preparation using entirely adiabatic methods, and is generally appliable to sizable number of atoms. Moreover, we experimentally validate the NQN scheme on the neutral-atom quantum cloud computer Aquila.

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