Speaker
Description
The excursion-set formalism provides a key connection between primordial inflationary fluctuations and the abundance of cosmic structures such as dark matter halos and voids, traditionally assuming Gaussian random walks. In this work, we extend this framework to fluctuations whose distribution present strongly non-Gaussian tails, beyond the reach of perturbative approaches to primordial non-Gaussianity based on statistical moment expansion. We address this problem with rigorous, analytical derivations relying on the large deviation principle, suited for the study of rare fluctuations. We derive new first-passage time distributions for random walks with non-Gaussian statistics and obtain updated predictions for the halo mass function. We also study the two-barrier first-passage problem relevant to cosmic void formation, leading to a new analytical prediction for the void size function, with improved accuracy on the larger scales. Our results demonstrate the potential of large deviation techniques as a bridge between inflationary scenarios often leading to strongly non-Gaussian tails and late-Universe observables.
| Other topic / keywords: | initial perturbations, non-gaussianities, large deviation principle, excursion-set theory, halos,voids |
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