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Main Authors: Morejon, Leonel, Rautenberg, Julian
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.16760
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author Morejon, Leonel
Rautenberg, Julian
author_facet Morejon, Leonel
Rautenberg, Julian
contents Photointeractions of ultra-high energy cosmic rays (UHECRs) in astro-physical scenarios are in general of stochastic nature and are often modeled with Monte Carlo methods to obtain the form of the distributions resulting from a sequence of interactions. These distributions are non trivial because the products resulting from each interaction as well as the number and distances covered by the secondary nuclear species are all random. In this work, a stochastic approach based on the theory of matrix exponential distributions is employed to describe the cascade distributions analytically and illustrate their potential for tracing the individual history of UHECRs, including inside the source. This analytic description has the advantage of better precision and considerably reduced computational cost in contrast to Monte Carlo codes, while requiring the same inputs: the interaction rates, the multiplicity, and the energy distributions of secondaries from a single interaction. The description of the composition evolution from in-source to extragalactic propagation (currently performed in separate simulations in the literature) is achieved here as a continuous distribution, using a gamma-ray burst scenario inspired by the event GRB170817A. Finally, the potential for locating a source based on the reconstructed UHECR origin employing this description is discussed under simplified general assumptions.
format Preprint
id arxiv_https___arxiv_org_abs_2502_16760
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Stochastic description of UHECR interactions
Morejon, Leonel
Rautenberg, Julian
High Energy Astrophysical Phenomena
Photointeractions of ultra-high energy cosmic rays (UHECRs) in astro-physical scenarios are in general of stochastic nature and are often modeled with Monte Carlo methods to obtain the form of the distributions resulting from a sequence of interactions. These distributions are non trivial because the products resulting from each interaction as well as the number and distances covered by the secondary nuclear species are all random. In this work, a stochastic approach based on the theory of matrix exponential distributions is employed to describe the cascade distributions analytically and illustrate their potential for tracing the individual history of UHECRs, including inside the source. This analytic description has the advantage of better precision and considerably reduced computational cost in contrast to Monte Carlo codes, while requiring the same inputs: the interaction rates, the multiplicity, and the energy distributions of secondaries from a single interaction. The description of the composition evolution from in-source to extragalactic propagation (currently performed in separate simulations in the literature) is achieved here as a continuous distribution, using a gamma-ray burst scenario inspired by the event GRB170817A. Finally, the potential for locating a source based on the reconstructed UHECR origin employing this description is discussed under simplified general assumptions.
title Stochastic description of UHECR interactions
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2502.16760