# P\'egase.3: A code for modeling the UV-to-IR/submm spectral and chemical   evolution of galaxies with dust

**Authors:** Michel Fioc (1, 2), Brigitte Rocca-Volmerange (1, 3) ((1), Institut d'astrophysique de Paris, (2) Sorbonne universit\'e, (3), Universit\'e Paris-sud)

arXiv: 1902.07929 · 2019-03-27

## TL;DR

Pégase.3 is an advanced computational tool that models the spectral and chemical evolution of galaxies from UV to submillimeter wavelengths, incorporating dust effects and stellar populations for accurate galaxy analysis.

## Contribution

It extends previous Pégase models to include far-IR/submm wavelengths, detailed dust modeling, and radiative transfer, providing comprehensive galaxy evolution simulations.

## Key findings

- Provides UV-to-submm SEDs for galaxies up to 20 Gyr
- Includes detailed dust and nebular emission modeling
- Outputs include galaxy colors, component masses, and dust properties

## Abstract

A code computing consistently the evolution of stars, gas and dust, as well as the energy they radiate, is required to derive reliably the history of galaxies by fitting synthetic SEDs to multiwavelength observations. The new code P\'egase.3 described in this paper extends to the far-IR/submm the UV-to-near-IR modeling provided by previous versions of P\'egase. It first computes the properties of single stellar populations at various metallicities. It then follows the evolution of the stellar light of a galaxy and the abundances of the main metals in the ISM, assuming some scenario of mass assembly and star formation. It simultaneously calculates the masses of the various grain families, the optical depth of the galaxy and the attenuation of the SED through the diffuse ISM in spiral and spheroidal galaxies, using grids of radiative transfer precomputed with Monte Carlo simulations taking scattering into account. The code determines the mean radiation field and the temperature probability distribution of stochastically heated individual grains. It then sums up their spectra to yield the overall emission by dust in the diffuse ISM. The nebular emission of the galaxy is also computed, and a simple modeling of the effects of dust on the SED of star-forming regions is implemented. The main outputs are UV-to-submm SEDs of galaxies from their birth up to 20 Gyr, colors, masses of galactic components, ISM abundances of metallic elements and dust species, supernova rates. The temperatures and spectra of individual grains are also available. The paper discusses several of these outputs for a scenario representative of Milky Way-like spirals. P\'egase.3 is fully documented and its Fortran 95 source files are public. The code should be especially useful for cosmological simulations and to interpret future mid- and far-IR data, whether obtained by JWST, LSST, Euclid or e-ELT.

## Full text

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## Figures

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## References

129 references — full list in the complete paper: https://tomesphere.com/paper/1902.07929/full.md

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Source: https://tomesphere.com/paper/1902.07929