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    Journals >High Power Laser and Particle Beams >Volume 36 >Issue 7 >Page 079001 > Article
    • High Power Laser and Particle Beams
    • Vol. 36, Issue 7, 079001 (2024)
    Research progress in radio technology based on Rydberg atoms
    Qing He1, Dong Li1,2, Li Gu1, Siyuan Luo1,2..., Yudong He1, Biao Li1 and Qiang Wang1,*|Show fewer author(s)
    Author Affiliations
  • 1Institute of Electronic Engineering, CAEP, Mianyang 621900, China
  • 2Microsystems and Terahertz Research Center, CAEP, Chengdu 610200, China
    • show less
    DOI: 10.11884/HPLPB202436.240061 Cite this Article
    Qing He, Dong Li, Li Gu, Siyuan Luo, Yudong He, Biao Li, Qiang Wang. Research progress in radio technology based on Rydberg atoms[J]. High Power Laser and Particle Beams, 2024, 36(7): 079001 Copy Citation Text show less
    Experimental set-up used for detecting microwave electric field[19]
    Fig. 1. Experimental set-up used for detecting microwave electric field[19]
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    Microwave detection based on EIT-AT[19]
    Fig. 2. Microwave detection based on EIT-AT[19]
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    Experimental system for measuring electric field by Mach-Zehnder interferometer[37]
    Fig. 3. Experimental system for measuring electric field by Mach-Zehnder interferometer[37]
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    In the atomic superheterodyne method, the local signal with known frequency and phase and the signal field to be measured are mixed by atoms[27]原子超外差法中,已知频率和相位的本地信号和待测信号场通过原子进行混频[27]
    Fig. 4. In the atomic superheterodyne method, the local signal with known frequency and phase and the signal field to be measured are mixed by atoms[27]原子超外差法中,已知频率和相位的本地信号和待测信号场通过原子进行混频[27]
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    Schematic diagram of optical repumping energy level[43]
    Fig. 5. Schematic diagram of optical repumping energy level[43]
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    Highly sensitive detection using traditional resonant cavity
    Fig. 6. Highly sensitive detection using traditional resonant cavity
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    Comparison of precision measurement using single (top) and many-body system (bottom)[48]
    Fig. 7. Comparison of precision measurement using single (top) and many-body system (bottom)[48]
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    Schematic diagram of microwave electric field detection using EIA effect in South China Normal University[44]
    Fig. 8. Schematic diagram of microwave electric field detection using EIA effect in South China Normal University[44]
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    Schematic diagram of experimental device of measuring K-band microwave by Shanxi University team using Rydberg atom[62]
    Fig. 9. Schematic diagram of experimental device of measuring K-band microwave by Shanxi University team using Rydberg atom[62]
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    Detection of MHz RF radio waves by Rydberg atomic system[67]
    Fig. 10. Detection of MHz RF radio waves by Rydberg atomic system[67]
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    Schematic diagram of atomic gas chamber detection with integrated electrode of Anderson research group[73]
    Fig. 11. Schematic diagram of atomic gas chamber detection with integrated electrode of Anderson research group[73]
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    Quasi-continuous transition frequencies and corresponding dipole moments from different alkali atoms[33]
    Fig. 12. Quasi-continuous transition frequencies and corresponding dipole moments from different alkali atoms[33]
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    Atomic radio receiver and spectrum analyzer prepared by Meyer et al using non-resonant heterodyne technique[81]
    Fig. 13. Atomic radio receiver and spectrum analyzer prepared by Meyer et al using non-resonant heterodyne technique[81]
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    Microwave electric field polarization measurement[84]
    Fig. 14. Microwave electric field polarization measurement[84]
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    Relationship between the measured parameters A and in the experiment, where A1 and A2 represent the areas of two spectral lines in the graph, with the solid line representing the theoretical results[14]实验中测量的参数A和的关系曲线,其中A1和A2表示插图中两条谱线的面积,实线为理论结果[14]
    Fig. 15. Relationship between the measured parameters A and in the experiment, where A1 and A2 represent the areas of two spectral lines in the graph, with the solid line representing the theoretical results[14]实验中测量的参数A和的关系曲线,其中A1A2表示插图中两条谱线的面积,实线为理论结果[14]
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    Shanxi University's experimental setup for measuring the scattering field of radio frequency identification (RFID) tag[86]
    Fig. 16. Shanxi University's experimental setup for measuring the scattering field of radio frequency identification (RFID) tag[86]
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    Measurement of polarization based on Rydberg atomic mixer[88]
    Fig. 17. Measurement of polarization based on Rydberg atomic mixer[88]
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    Two-dimensional imaging results[90]
    Fig. 18. Two-dimensional imaging results[90]
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    Using a quantum sensor based on thermal Rydberg atoms to receive data encoded in electromagnetic fields in the extreme electrically small regime[93]
    Fig. 19. Using a quantum sensor based on thermal Rydberg atoms to receive data encoded in electromagnetic fields in the extreme electrically small regime[93]
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    Experimental schematic of NIST using atomic mixer to realize phase measurement[104]
    Fig. 20. Experimental schematic of NIST using atomic mixer to realize phase measurement[104]
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    propertyn dependence
    binding energyn−2
    energy spacingn−3
    orbital radiusn2
    dipole momentn2
    radiative lifetimen3
    polarizabilityn7
    van der Waals interactionn11
    dipole-dipole interactionn4
    Table 1. The main characteristics of Rydberg atoms
    Abstract
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    References (111)
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    Qing He, Dong Li, Li Gu, Siyuan Luo, Yudong He, Biao Li, Qiang Wang. Research progress in radio technology based on Rydberg atoms[J]. High Power Laser and Particle Beams, 2024, 36(7): 079001
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