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    Journals >High Power Laser and Particle Beams >Volume 34 >Issue 6 >Page 063005 > Article
    • High Power Laser and Particle Beams
    • Vol. 34, Issue 6, 063005 (2022)
    Cold cavity characteristics of a new type of low-inductance magnetically insulated transmission line
    Yan Liu1, Laqun Liu1、*, Liangji Zhou2, Jihao Jiang2, Dagang Liu1, Huihui Wang1, and Qi’ang Wang1
    Author Affiliations
  • 1School of Electronic Science and Engineering, University of Electronic Science and Technology of China, Chengdu 610054, China
  • 2Institute of Fluid Physics, CAEP, Mianyang 621900, China
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    DOI: 10.11884/HPLPB202234.210494 Cite this Article
    Yan Liu, Laqun Liu, Liangji Zhou, Jihao Jiang, Dagang Liu, Huihui Wang, Qi’ang Wang. Cold cavity characteristics of a new type of low-inductance magnetically insulated transmission line[J]. High Power Laser and Particle Beams, 2022, 34(6): 063005 Copy Citation Text show less
    New low-inductance MITL cross-sectional configuration
    Fig. 1. New low-inductance MITL cross-sectional configuration
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    Periodic structure diagram of a single petal
    Fig. 2. Periodic structure diagram of a single petal
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    Half-petal cycle 3D model section view
    Fig. 3. Half-petal cycle 3D model section view
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    Simulation and theoretical value of electric field distribution at different observation points of petal-shaped
    Fig. 4. Simulation and theoretical value of electric field distribution at different observation points of petal-shaped
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    Simulation and theoretical values of magnetic field distribution at different observation points of petal-shaped
    Fig. 5. Simulation and theoretical values of magnetic field distribution at different observation points of petal-shaped
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    Isometric map of petal-shaped electric field
    Fig. 6. Isometric map of petal-shaped electric field
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    Isometric map of petal-shaped magnetic field
    Fig. 7. Isometric map of petal-shaped magnetic field
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    Spatial variation of electric field from petal-shaped cathode to anode
    Fig. 8. Spatial variation of electric field from petal-shaped cathode to anode
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    Spatial variation of the magnetic field from petal-shaped cathode to the anode
    Fig. 9. Spatial variation of the magnetic field from petal-shaped cathode to the anode
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    pointtheoretical calculation/(MV·m−1) chipic simulation/(MV·m−1) relative error/%
    small circle segmentP1497.2499.00.3
    P2497.2500.40.6
    parallel plate segmentP3500.0500.30.1
    P4500.0500.40.1
    P5500.0500.30.1
    great circle segment P6499.5500.90.3
    P7499.5500.90.1
    Table 1. Comparison of electric field distribution between theoretical calculation and Chipic simulation point
    theoretical calculation/Tchipic simulation/Trelative error/%
    small circle segmentP11.6481.6641.0
    P21.6481.6691.3
    parallel plate segmentP31.6531.6691.0
    P41.6531.6691.0
    P51.6531.6701.0
    great circle segmentP61.6521.6711.2
    P71.6521.6681.0
    Table 2. Comparison of magnetic field distribution between theoretical calculation and Chipic simulation point
    Abstract
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    Equations (10)
    References (12)
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    Yan Liu, Laqun Liu, Liangji Zhou, Jihao Jiang, Dagang Liu, Huihui Wang, Qi’ang Wang. Cold cavity characteristics of a new type of low-inductance magnetically insulated transmission line[J]. High Power Laser and Particle Beams, 2022, 34(6): 063005
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