Neutrino Fast Flavor Pendulum. Part 2: Collisional Damping

Abstract

In compact astrophysical objects, the neutrino density can be so high that neutrino-neutrino refraction can lead to fast flavor conversion of the kind e e x x with x=μ,τ, depending on the neutrino angle distribution. Previously, we have shown that in a homogeneous, axisymmetric two-flavor system, these collective solutions evolve in analogy to a gyroscopic pendulum. In flavor space, its deviation from the weak-interaction direction is quantified by a variable that moves between +1 and min, the latter following from a linear mode analysis. As a next step, we include collisional damping of flavor coherence, assuming a common damping rate for all modes. Empirically we find that the damped pendular motion reaches an asymptotic level of pair conversion f=A+(1-A) min (numerically A 0.370) that does not depend on details of the angular distribution (except for fixing min), the initial seed, nor . On the other hand, even a small asymmetry between the neutrino and antineutrino damping rates strongly changes this picture and can even enable flavor instabilities in otherwise stable systems.