Computational Model for Photoionization in Pure SF6 Streamer

Photoionization plays a crucial role in achieving spatial numerical convergence and accurate quantitative predictions in SF6 streamer simulations, but accurate models for SF6 photoionization remains limited, motivating this paper. First, we develop a computational model for SF6 photoionization and provide the detailed modeling process. Then, we perform comparative studies against simplified approaches. The results demonstrate that the proposed model effectively captures the non-local effects of SF6 photoionization, enhancing both the spatial numerical convergence and the accuracy of the streamer structure. Finally, we perform comparative studies by artificially increasing the photoionization intensity through multiplying the photoionization source term Sph by a factor of 10 (10*Sph) relative to the baseline intensity. Regarding breakdown voltage prediction, 10*Sph leads to a significant underestimation of the breakdown voltage for positive streamers, introducing errors greater than 0.5 kV, while exerting a relatively small impact on negative streamers. Regarding streamer propagation dynamics, 10*Sph reduces the contraction at the positive streamer head and significantly lowers the local field by more than 700 Td, thereby slowing down its speed. In contrast, 10*Sph has little impact on the morphology of the negative streamers and slightly enhances the local field by less than 200 Td, thereby consistently accelerating its propagation.