Related papers: Observation of quantum superposition of topological defects in a trapped ion quantum simulator

Observation of quantum superposition of topological defects in a trapped ion quantum simulator

URL: http://arxiv.org/abs/2410.15389v1
Date: Sun, 20 Oct 2024 13:27:13 GMT
Title: Observation of quantum superposition of topological defects in a trapped ion quantum simulator
Authors: Zhijie Cheng, Yukai Wu, Shijiao Li, Quanxin Mei, Bowen Li, Gangxi Wang, Yue Jiang, Binxiang Qi, Zichao Zhou, Panyu Hou, Luming Duan,
Abstract summary: We report the observation of quantum superposition of topological defects in a trapped-ion quantum simulator. Our work provides useful tools for non-equilibrium dynamics in quantum Kibble-Zurek physics.
Score: 10.307677845109378
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Abstract: Topological defects are discontinuities of a system protected by global properties, with wide applications in mathematics and physics. While previous experimental studies mostly focused on their classical properties, it has been predicted that topological defects can exhibit quantum superposition. Despite the fundamental interest and potential applications in understanding symmetry-breaking dynamics of quantum phase transitions, its experimental realization still remains a challenge. Here, we report the observation of quantum superposition of topological defects in a trapped-ion quantum simulator. By engineering long-range spin-spin interactions, we observe a spin kink splitting into a superposition of kinks at different positions, creating a ``Schrodinger kink'' that manifests non-locality and quantum interference. Furthermore, by preparing superposition states of neighboring kinks with different phases, we observe the propagation of the wave packet in different directions, thus unambiguously verifying the quantum coherence in the superposition states. Our work provides useful tools for non-equilibrium dynamics in quantum Kibble-Zurek physics.

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