Realization of fractional quantum Hall state with interacting photons

Fractional quantum Hall (FQH) states are known for their robust topological order and possess properties that are appealing for applications in fault-tolerant quantum computing. An engineered quantum platform would provide opportunities to operate FQH states without an external magnetic field and en...

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Bibliographic Details
Published in:Science (American Association for the Advancement of Science) 2024-05, Vol.384 (6695), p.579-584
Main Authors: Wang, Can, Liu, Feng-Ming, Chen, Ming-Cheng, Chen, He, Zhao, Xian-He, Ying, Chong, Shang, Zhong-Xia, Wang, Jian-Wen, Huo, Yong-Heng, Peng, Cheng-Zhi, Zhu, Xiaobo, Lu, Chao-Yang, Pan, Jian-Wei
Format: Article
Language:English
Subjects:
Condensed matter physics
Electron states
Fault tolerance
Magnetic fields
Photons
Physics
Quantum computing
Quantum Hall effect
Quantum theory
Qubits (quantum computing)
Superconductivity
Topology
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Summary:Fractional quantum Hall (FQH) states are known for their robust topological order and possess properties that are appealing for applications in fault-tolerant quantum computing. An engineered quantum platform would provide opportunities to operate FQH states without an external magnetic field and enhance local and coherent manipulation of these exotic states. We demonstrate a lattice version of photon FQH states using a programmable on-chip platform based on photon blockade and engineering gauge fields on a two-dimensional circuit quantum electrodynamics system. We observe the effective photon Lorentz force and butterfly spectrum in the artificial gauge field, a prerequisite for FQH states. After adiabatic assembly of Laughlin FQH wave function of 1/2 filling factor from localized photons, we observe strong density correlation and chiral topological flow among the FQH photons. We then verify the unique features of FQH states in response to external fields, including the incompressibility of generating quasiparticles and the smoking-gun signature of fractional quantum Hall conductivity. Our work illustrates a route to the creation and manipulation of novel strongly correlated topological quantum matter composed of photons and opens up possibilities for fault-tolerant quantum information devices.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.ado3912