# The Orion Region: Evidence of enhanced cosmic-ray density in a stellar   wind forward shock interaction with a high density shell

**Authors:** Martina Cardillo, Nicola Marchili, Giovanni Piano, Andrea Giuliani,, Marco Tavani, Sergio Molinari

arXiv: 1901.01764 · 2019-01-30

## TL;DR

This study investigates whether cosmic-ray re-acceleration at the stellar wind shock of k-Ori explains the gamma-ray excess in the Orion region, suggesting re-acceleration of existing cosmic rays as a plausible mechanism.

## Contribution

The paper develops a physical model demonstrating that cosmic-ray re-acceleration at the k-Ori shock can account for observed gamma-ray excess, highlighting a new potential acceleration process.

## Key findings

- Gamma-ray excess explained by re-acceleration of pre-existing cosmic rays.
- Adiabatic compression of the shell could also produce similar gamma-ray emission.
- Freshly accelerated particles likely play a minor role compared to re-acceleration.

## Abstract

Context. In recent years, an in-depth gamma-ray analysis of the Orion region has been carried out by the AGILE and Fermi-LAT (Large Area Telescope) teams with the aim of estimating the H2-CO conversion factor, XCO. The comparison of the data from both satellites with models of diffuse gamma-ray Galactic emission unveiled an excess at (l,b)=[213.9, -19.5], in a region at a short angular distance from the OB star k-Ori. Possible explanations of this excess are scattering of the so-called "dark gas", non-linearity in the H2-CO relation, or Cosmic-Ray (CR) energization at the k-Ori wind shock.   Aims. Concerning this last hypothesis, we want to verify whether cosmic-ray acceleration or re-acceleration could be triggered at the k-Ori forward shock, which we suppose to be interacting with a star-forming shell detected in several wavebands and probably triggered by high energy particles.   Methods. Starting from the AGILE spectrum of the detected gamma-ray excess, showed here for the first time, we developed a valid physical model for cosmic-ray energization, taking into account re-acceleration, acceleration, energy losses, and secondary electron contribution.   Results. Despite the characteristic low velocity of an OB star forward shock during its "snowplow" expansion phase, we find that the Orion gamma-ray excess could be explained by re-acceleration of pre-existing cosmic rays in the interaction between the forward shock of k-Ori and the CO-detected, star-forming shell swept-up by the star expansion. According to our calculations, a possible contribution from freshly accelerated particles is sub-dominant with respect the re-acceleration contribution. However, a simple adiabatic compression of the shell could also explain the detected gamma-ray emission. Futher GeV and TeV observations of this region are highly recommended in order to correctly identify the real physical scenario.

## Full text

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## Figures

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## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1901.01764/full.md

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Source: https://tomesphere.com/paper/1901.01764