Systematic local simulations of fast neutrino flavor conversions with scattering effects

We investigate the dynamics of fast neutrino flavor conversions (FFCs) in the one-dimensional (1D) inhomogeneous and the homogeneous models as post processes by employing snapshots obtained by our self-consistent, realistic Boltzmann simulations in two spatial dimensions (2D). We show that the FFC growth rate is considerably larger in the inhomogeneous model than in the homogeneous model, as expected from the previous linear analysis results. We find that the momentum space dimension does not significantly influence the neutrino transition probability under inhomogeneous conditions. On the other hand, in the homogeneous model without collisions, the FFC depends on the momentum space, and the azimuthal angle dependence breaks the periodicity of the FFC. Our study demonstrates that collision-induced enhancement occurs on a long time scale in the inhomogeneous model. Despite that collision-induced enhancement does not appear on the short time scale, that should be taken into account to predict the final conversion probability.