In the standard model neutrinos are assumed to have streamed across the Universe since they last scattered when the standard-model plasma temperature was similar to MeV. The shear stress of free-streaming neutrinos imprints itself gravitationally on the cosmic microwave background (CMB) and makes the CMB a sensitive probe of neutrino scattering. Yet, the presence of nonstandard physics in the neutrino sector may alter this standard chronology and delay neutrino free streaming until a much later epoch. We use observations of the CMB to constrain the strength of neutrino self interactions G(eff) and put limits on new physics in the neutrino sector from the early Universe. Within the context of conventional Lambda CDM parameters cosmological data are compatible with G(eff) less than or similar to 1/(56 MeV)(2) and neutrino free streaming might be delayed until their temperature has cooled to as low as similar to 25 eV. Intriguingly, we also find an alternative cosmology compatible with cosmological data in which neutrinos scatter off each other until z similar to 10(4) with a preferred interaction strength in a narrow region around G(eff) similar or equal to 1/(10MeV)(2) similar or equal to 8.6x10(8) G(F), where G(F) is the Fermi constant. This distinct self-interacting neutrino cosmology is characterized by somewhat lower values of both the scalar spectral index and the amplitude of primordial fluctuations. While we phrase our discussion here in terms of a specific scenario, our constraints on the neutrino visibility function are very general.

• 出版日期2014-12-29