Your search keyword '"Li, Xiangbei"' showing total 7 results

1. Quantum metrological capability as a probe for quantum phase transition

Author

Li, Xiangbei, Chu, Yaoming, Zhang, Shaoliang, and Cai, Jianming

Subjects

Quantum Physics

Abstract

The comprehension of quantum phase transitions (QPTs) is considered as a critical foothold in the field of many-body physics. Developing protocols to effectively identify and understand QPTs thus represents a key but challenging task for present quantum simulation experiments. Here, we establish a dynamical quench-interferometric framework to probe a zero-temperature QPT, which utilizes the evolved state by quenching the QPT Hamiltonian as input of a unitary interferometer. The metrological capability quantified by the quantum Fisher information captivatingly shows an unique peak in the vicinity of the quantum critical point, allowing us to probe the QPT without cooling the system to its ground state. We show that the probing can be implemented by extracting quantum fluctuations of the interferometric generator as well as parameter estimation uncertainty of the interferometric phase, and subsequently allows identifying the boundary of the phase diagram. Our results establish an important link between QPTs and quantum metrology, and enrich the toolbox of studying non-equilibrium many-body physics in current quantum simulators., Comment: Comments are welcome!

Published

2024

2. Quantum delocalization on correlation landscape: The key to exponentially fast multipartite entanglement generation

Author

Chu, Yaoming, Li, Xiangbei, and Cai, Jianming

Subjects

Quantum Physics

Abstract

Entanglement, a hallmark of quantum mechanics, is a vital resource for quantum technologies. Generating highly entangled multipartite states is a key goal in current quantum experiments. We unveil a novel framework for understanding entanglement generation dynamics in Hamiltonian systems by quantum delocalization of an effective operator wavefunction on a correlation landscape. Our framework establishes a profound connection between the exponentially fast generation of multipartite entanglement, witnessed by the quantum Fisher information, and the linearly increasing asymptotics of hopping amplitudes governing the delocalization dynamics in Krylov space. We illustrate this connection using the paradigmatic Lipkin-Meshkov-Glick model and highlight potential signatures in chaotic Feingold-Peres tops. Our results provide a transformative tool for understanding and harnessing rapid entanglement production in complex quantum systems, providing a pathway for quantum enhanced technologies by large-scale entanglement.

Published

2024

3. Strong quantum metrological limit from many-body physics

Author

Chu, Yaoming, Li, Xiangbei, and Cai, Jianming

Subjects

Quantum Physics

Abstract

Surpassing the standard quantum limit and even reaching the Heisenberg limit using quantum entanglement, represents the Holy Grail of quantum metrology. However, quantum entanglement is a valuable resource that does not come without a price. The exceptional time overhead for the preparation of large-scale entangled states raises disconcerting concerns about whether the Heisenberg limit is fundamentally achievable. Here we find a universal speed limit set by the Lieb-Robinson light cone for the quantum Fisher information growth to characterize the metrological potential of quantum resource states during their preparation. Our main result establishes a strong precision limit of quantum metrology accounting for the complexity of many-body quantum resource state preparation and reveals a fundamental constraint for reaching the Heisenberg limit in a generic many-body lattice system with bounded one-site energy. It enables us to identify the essential features of quantum many-body systems that are crucial for achieving the quantum advantage of quantum metrology, and brings an interesting connection between many-body quantum dynamics and quantum metrology., Comment: 7 pages, 3 figures + supplementary information (14 pages)

Published

2023

4. Experimental demonstration of topological bounds in quantum metrology

Author

Yu, Min, Li, Xiangbei, Chu, Yaoming, Mera, Bruno, Ünal, F. Nur, Yang, Pengcheng, Liu, Yu, Goldman, Nathan, and Cai, Jianming

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases

Abstract

Quantum metrology is deeply connected to quantum geometry, through the fundamental notion of quantum Fisher information. Inspired by advances in topological matter, it was recently suggested that the Berry curvature and Chern numbers of band structures can dictate strict lower bounds on metrological properties, hence establishing a strong connection between topology and quantum metrology. In this work, we provide a first experimental verification of such topological bounds, by performing optimal quantum multi-parameter estimation and achieving the best possible measurement precision. By emulating the band structure of a Chern insulator, we experimentally determine the metrological potential across a topological phase transition, and demonstrate strong enhancement in the topologically non-trivial regime. Our work opens the door to metrological applications empowered by topology, with potential implications for quantum many-body systems., Comment: 6 pages, 4 figures + 13 pages (SI), comments are welcome

Published

2022

5. Experimental demonstration of topological bounds in quantum metrology.

Author

Yu, Min, Li, Xiangbei, Chu, Yaoming, Mera, Bruno, Ünal, F Nur, Yang, Pengcheng, Liu, Yu, Goldman, Nathan, and Cai, Jianming

Subjects

*PHASE transitions, *GEOMETRIC quantization, *FISHER information, *SELF-efficacy, *METROLOGY

Abstract

Quantum metrology is deeply connected to quantum geometry, through the fundamental notion of quantum Fisher information. Inspired by advances in topological matter, it was recently suggested that the Berry curvature and Chern numbers of band structures can dictate strict lower bounds on metrological properties, hence establishing a strong connection between topology and quantum metrology. In this work, we provide a first experimental verification of such topological bounds, by performing optimal quantum multi-parameter estimation and achieving the best possible measurement precision. By emulating the band structure of a Chern insulator, we experimentally determine the metrological potential across a topological phase transition, and demonstrate strong enhancement in the topologically non-trivial regime. Our work opens the door to metrological applications empowered by topology, with potential implications for quantum many-body systems. [ABSTRACT FROM AUTHOR]

Published

2024

6. Strong Quantum Metrological Limit from Many-Body Physics

Author

Chu, Yaoming, primary, Li, Xiangbei, additional, and Cai, Jianming, additional

Published

2023

7. An Efficient Agrobacterium rhizogenes-Mediated Hairy Root Transformation Method in a Soybean Root Biology Study

Author

Huang, Penghui, primary, Lu, Mingyang, additional, Li, Xiangbei, additional, Sun, Huiyu, additional, Cheng, Zhiyuan, additional, Miao, Yuchen, additional, Fu, Yongfu, additional, and Zhang, Xiaomei, additional

Published

2022