Abstract
Context. Measuring star formation across the Universe is key to constrain models of galaxy formation and evolution. Yet, determining the SFR (star formation rate) of galaxies remains a challenge. Aims. In this paper we investigate in isolation the impact of a variable star formation history on the measurement of the SFR. Methods. We combine 23 state-of-the-art hydrodynamical simulations of 1<z<2 galaxies on the main sequence with the cigale spectral energy distribution modelling code. This allows us to generate synthetic spectra every 1 Myr for each simulation, taking the stellar populations and the nebular emission into account. Using these spectra, we estimate the SFR from classical estimators which we compare with the true SFR we know from the simulations. Results. We find that except for the Lyman continuum, classical SFR estimators calibrated over 100 Myr overestimate the SFR from ~25% in the FUV band to ~65% in the U band. Such biases are due 1) to the contribution of stars living longer than 100 Myr, and 2) to variations of the SFR on timescales longer than a few tens of Myr. Rapid variations of the SFR increase the uncertainty on the determination of the instantaneous SFR but have no long term effect. Conclusions. The discrepancies between the true and estimated SFR may explain at least part of the tension between the integral of the star formation rate density and the stellar mass density at a given redshift. To reduce possible biases, we suggest to use SFR estimators calibrated over 1 Gyr rather than the usually adopted 100 Myr timescales.
Highlights
The star formation rate (SFR) is a key parameter to understand galaxy formation and evolution
We find that SFR(Ly) follows very closely the true SFR and is able to capture all but the highest frequency variations for which it suffers from a short time delay
If the overestimate is very small for SFR(Ly) it is clearly visible for SFR(FUV) and SFR(NUV), and it is strong for SFR(U): we find [SFR(FUV) − SFR(true)] /SFR(true) = 0.27 ± 0.30 and [SFR(U) − SFR(true)] /SFR(true) = 0.70 ± 0.46 between 250 Myr and 790 Myr
Summary
The star formation rate (SFR) is a key parameter to understand galaxy formation and evolution. If the SFR plays such a central role, this is because of its fundamental relation to the stellar mass and the gas reservoir on which our understanding of galaxy formation and evolution is based. One of the key assumptions to measure the SFR of a galaxy is its star formation history (SFH). If this assumption seems reasonable for low redshift spiral galaxies evolving secularly, it is unlikely to hold true for interacting systems or at higher redshift where the SFR necessarily varies on timescales that can be similar or shorter than 100 Myr. With the increasing availability of observations spanning a broad range of wavelengths, one possibility for waiving the assumption on the SFH is to carry out multi-wavelength spectral energy distribution (SED) modelling. If multi-wavelength data partly alleviate this problem when UV and infrared (IR) data are simultaneously available, the SFH still remains poorly constrained
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