# Calibrating star-formation rate prescriptions at different scales (10 pc   to 1 kpc) in M31

**Authors:** Neven Tomicic, I-Ting Ho, Kathryn Kreckel, Eva Schinnerer, Adam Leroy,, Brent Groves, Karin Sandstrom, Guillermo A. Blanc, Thomas Jarrett, David, Thilker, Maria Kapala, Rebecca McElroy

arXiv: 1901.11321 · 2019-03-06

## TL;DR

This study calibrates star formation rate prescriptions in M31 at various scales, revealing that dust geometry and galaxy orientation significantly influence SFR estimates, especially at large galacto-centric distances.

## Contribution

It provides new calibration factors for SFR prescriptions in M31 and highlights the impact of dust distribution and galaxy inclination on SFR measurements.

## Key findings

- SFR prescriptions are consistent across scales in M31.
- Calibration factors are five times higher than literature values.
- Extended dust layers affect attenuation and SFR estimates.

## Abstract

We calibrate commonly used star formation rate (SFR) prescriptions using observations in five kpc-sized fields in the nearby galaxy Andromeda (M31) at 10\,pc spatial resolution. Our observations at different scales enable us to resolve the star-forming regions and to distinguish them from non star-forming components. We use extinction corrected H$\alpha$ from optical integral field spectroscopy as our reference tracer and have verified its reliability via tests. It is used to calibrate monochromatic and hybrid (H$\alpha$+a$\times$IR and FUV+b$\times$IR) SFR prescriptions, which use FUV (GALEX), 22\,$\mu$m (WISE) and 24\,$\mu$m (MIPS). Additionally, we evaluate other multi-wavelength infra-red tracers. Our results indicate that the SFR prescriptions do not change (in M31) with spatial scales or with subtraction of the diffuse component. For the calibration factors in the hybrid SFR prescriptions, we find a$\approx$0.2 and b$\approx$22 in M31, which are a factor of 5 higher than in the literature. As the fields in M31 exhibit high attenuation and low dust temperatures, lie at large galacto-centric distances, and suffer from high galactic inclination compared to measurements in other galaxies, we propose that the fields probe a dust layer extended along the line of sight that is not directly spatially associated with star-forming regions. This (vertically) extended dust component increases the attenuation and alters the SFR prescriptions in M31 compared to literature measurements. We recommend that SFR prescriptions should be applied with caution at large galacto-centric distances and in highly inclined galaxies, due to variations in the relative (vertical) distribution of dust and gas.

## Full text

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## Figures

23 figures with captions in the complete paper: https://tomesphere.com/paper/1901.11321/full.md

## References

121 references — full list in the complete paper: https://tomesphere.com/paper/1901.11321/full.md

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Source: https://tomesphere.com/paper/1901.11321