Simulation of energy and fluence dependence of heavy ion induced displacement damage factor in bipolar junction transistor

This article presents the theoretical calculation of the variation of displacement damage factors as a function of energy and rad equivalent fluence in bipolar junction transistor for various particulate radiation viz., He, Si, Cl, Ti, Ni, Br, Ag, I, and Au. The calculation is based on the experimental data on γ-ray induced gain degradation in a commercial space borne BJT (2N3019). The method involves the calculation of γ-ray dose (rad(Si)) equivalent of effective particle fluence. The linear energy transfer (LET) in silicon for different particle radiation obtained from TRIM calculation has been used for the conversion of γ-dose into fluence of various particles. The estimation predicts a smooth increase in the displacement damage factor as the mass of the ion increases. Further, the displacement damage factor reaches a maximum at the same value of energy, which corresponds to maximum LET for all heavy ions. The maximum value of damage factor marginally decreases with increasing ion fluence for an ion of given energy. The results are compared with the data available in the literature for proton, deuteron, and helium induced displacement damage.