Abstract
A systematic design of secondary magnetically insulated transmission line (MITL) for a 3.8-MV gamma-ray radiation facility is proposed. To produce appropriate dose rate of gamma-ray under the condition of reliable insulation, an equivalent circuit model including inductive cavity, MITL, and gamma-ray diode is established. Impedance and transmission time of MITL are detailly analyzed and optimally designed. More precisely, a particle-in-cell (PIC) model is developed to calculate loss-front velocity, operation impedance, and output parameters. The results are coincident with the circuit model and meet the design requirements.
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