# Insights on star formation histories and physical properties of $1.2   \leq z \lesssim 4 $ Herschel-detected galaxies

**Authors:** P. Sklias, D. Schaerer, D. Elbaz, M. Pannella, C. Schreiber, A. Cava

arXiv: 1705.01174 · 2017-09-13

## TL;DR

This study investigates the star formation histories and physical properties of high-redshift Herschel-detected galaxies, revealing trends in SFHs, the impact of IR constraints, and their relation to cosmic star formation history.

## Contribution

It introduces a flexible SED fitting approach using variable SFHs and IR constraints, providing new insights into galaxy evolution at high redshift.

## Key findings

- Declining SFHs can better fit certain galaxies, indicating possible post-starburst phases.
- Including IR luminosity constraints influences the preferred SFH models, especially at high redshift.
- The global SFH aligns with the cosmic star formation history and supports the downsizing scenario.

## Abstract

We test the impact of using variable star forming histories (SFHs) and the use of the IR luminosity (LIR) as a constrain on the physical parameters of high redshift dusty star-forming galaxies. We explore in particular the stellar properties of galaxies in relation with their location on the SFR-M* diagram. We perform SED fitting of the UV-NIR and FIR emissions of a large sample of GOODS-Herschel galaxies, for which rich multi-wavelength observations are available. We test different SFHs and imposing energy conservation in the SED fitting process, to face issues like the age-extinction degeneracy and produce SEDs consistent with observations. Our models work well for the majority of the sample, with the notable exception of the high LIR end, for which we have indications that our simple energy conservation approach cannot hold true. We find trends in the SFHs fitting our sources depending on stellar mass M* and z. Trends also emerge in the characteristic timescales of the SED models depending on the location on the SFR-M* diagram. We show that whilst using the same available observational data, we can produce galaxies less star-forming than usually inferred, if we allow declining SFHs, while properly reproducing their observables. These sources can be post-starbursts undergoing quenching, and their SFRs are potentially overestimated if inferred from their LIR. Fitting without the IR constrain leads to a strong preference for declining SFHs, while its inclusion increases the preference of rising SFHs, more so at high z, in tentative agreement with the cosmic star formation history. Keeping in mind that the sample is biased towards high LIR, the evolution shaped by our model appears as both bursty (initially) and steady-lasting (later on). The global SFH of the sample follows the cosmic SFH with a small scatter, and is compatible with the "downsizing" scenario of galaxy evolution.

## Full text

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## Figures

36 figures with captions in the complete paper: https://tomesphere.com/paper/1705.01174/full.md

## References

84 references — full list in the complete paper: https://tomesphere.com/paper/1705.01174/full.md

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Source: https://tomesphere.com/paper/1705.01174