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Effects of primordial fluctuations on relic neutrino simulations

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arxiv 2407.14582 v2 pith:75Z2DH44 submitted 2024-07-19 astro-ph.CO hep-ph

Effects of primordial fluctuations on relic neutrino simulations

classification astro-ph.CO hep-ph
keywords anisotropieseffectsneutrinorelicconditionsdistributionfluctuationshalo
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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After decoupling, relic neutrinos traverse the evolving gravitational imhomogeneities along their trajectories. Once they turn non-relativistic, this results in a significant amplification of the anisotropies in the cosmic neutrino background (C$\nu$B). Past studies have reconstructed the phase-space distribution of relic neutrinos from the local distribution of matter (accounting for the Milky Way halo and the surrounding large-scale structures), but have neglected the C$\nu$B anisotropies in the initial conditions of neutrino trajectories. Using our previously developed N-1-body simulation framework, we show that including these primordial fluctuations in the initial conditions can be important, as it produces similar effects on the abundance and anisotropies of the C$\nu$B as the inclusion of large-scale structures beyond the Milky Way halo. Interpretability of data from future C$\nu$B observatories like PTOLEMY therefore depends on correctly modelling these effects.

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