Monte Carlo Simulation of Transient Response of Coaxial Cable Irradiated by Intense Pulsed Gamma Rays

Abstract

To obtain the transient current law of typical coaxial cable irradiated by intense pulsed gamma rays, the irradiation effect experiment of intense pulsed gamma rays on typical coaxial cable was carried out on the “Qiangguang-1” accelerator, and the relationship between the amplitude of pulsed current in the center conductor of coaxial cable and the instantaneous gamma dose rate was measured. The simulation model of irradiation effect of intense pulsed gamma rays on the coaxial cable is presented. By using the Monte Carlo particle transport method, the electron charge deposition rate in the center conductor and the outer shielding conductor of different types of coaxial cables under intense pulsed gamma irradiation is calculated. The calculated results are basically consistent with the experimental results. When the gamma ray energy is greater than 0.6 MeV, the electron charge deposition rate in the center conductor of coaxial cable first increases, then decreases, and then increases with the increase of gamma ray energy. When the gamma ray energy is greater than 0.1 MeV, the number of electrons deposited in the center conductor of the cable per unit length increases with the increase of gamma ray energy. The number of electron charges deposited in the outer shielding conductor layer is greater than that deposited in the center conductor for typical coaxial cable. The gamma radiation sensitivity of the coaxial cable increases at the same gamma ray intensity when the cable is obliquely irradiated.