Abstract
We consider the decoherence effects in the propagation of neutrinos in a background composed of a scalar particle and a fermion due to the non-forward neutrino scattering processes. Using a simple model for the coupling of the form $\bar f_R\nu_L\phi$ we calculate the contribution to the imaginary part of the neutrino self-energy arising from the non-forward neutrino scattering processes in such backgrounds, from which the damping terms are determined. In the case we are considering, in which the initial neutrino state is depleted but does not actually disappear (the initial neutrino transitions into a neutrino of a different flavor but does not decay into a $f\phi$ pair, for example), we associate the damping terms with decoherence effects. For this purpose we give a precise prescription to identify the decoherence terms, as used in the context of the master or Linblad equation, in terms of the damping terms we have obtained from the calculation of the imaginary part of the neutrino self-energy from the non-forward neutrino scattering processes. The results can be directly useful in the context of Dark Matter-neutrino interaction models in which the scalar and/or fermion constitute the dark-matter, and can also serve to guide the generalizations to other models and/or situations in which the decoherence effects in the propagation of neutrinos originate from the non-forward scattering processes may be important. As a guide to estimating such decoherence effects, the contributions to the absorptive part of the self-energy and the corresponding damping terms are computed explicitly in the context of the model we consider, for several limiting cases of the momentum distribution functions of the background particles.
Highlights
AND SUMMARYSeveral extensions of the standard electroweak theory involve the coupling of neutrinos to scalar particles (φ) and fermions (f) of the generic form f RνLφ
A scalar particle and a fermion with an interaction of the form given in Eq (1.1), due to the nonforward neutrino scattering processes
We calculated the contribution to the imaginary part of the neutrino thermal selfenergy arising from the nonforward neutrino scattering processes in such backgrounds, from which the damping matrix is determined
Summary
Several extensions of the standard electroweak theory involve the coupling of neutrinos to scalar particles (φ) and fermions (f) of the generic form f RνLφ. Here we consider various neutrino flavors (νLa) interacting with a scalar and fermion with a coupling of the form X In this case, the scattering processes of the form νa þ x → νb þ x, where x 1⁄4 f, φ, can induce decoherence effects in the propagation of neutrinos, independently of the possible damping effects already mentioned. As a guide to estimating such decoherence effects, the contributions to the absorptive part of the self-energy and the corresponding damping terms are computed explicitly in the context of the model we consider, for several limiting cases of the momentum distribution functions of the background particles. VI, and some details of the derivations are provided in the Appendix
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