Abstract
Aims. The path towards robust near-infrared extensions of stellar population models involves the confrontation between empirical and synthetic stellar spectral libraries across the wavelength ranges of photospheric emission. Indeed, the theory of stellar emission enters all population synthesis models, even when this is only implicit in the association of fundamental stellar parameters with empirical spectral library stars. With its near-ultraviolet to near-infrared coverage, the X-shooter Spectral Library (XSL) allows us to examine to what extent models succeed in reproducing stellar energy distributions (SEDs) and stellar absorption line spectra simultaneously. Methods. As a first example, this study compares the stellar spectra of XSL with those of the Göttingen Spectral Library, which are based on the PHOENIX synthesis code. The comparison was carried out both separately in the three arms of the X-shooter spectrograph known as UVB, VIS and NIR, and jointly across the whole spectrum. We did not discard the continuum in these comparisons; only reddening was allowed to modify the SEDs of the models. Results. When adopting the stellar parameters published with data release DR2 of XSL, we find that the SEDs of the models are consistent with those of the data at temperatures above 5000 K. Below 5000 K, there are significant discrepancies in the SEDs. When leaving the stellar parameters free to adjust, satisfactory representations of the SEDs are obtained down to about 4000 K. However, in particular below 5000 K and in the UVB spectral range, strong local residuals associated with intermediate resolution spectral features are then seen; the necessity of a compromise between reproducing the line spectra and reproducing the SEDs leads to dispersion between the parameters favored by various spectral ranges. We describe the main trends observed and we point out localized offsets between the parameters preferred in this global fit to the SEDs and the parameters in DR2. These depend in a complex way on the position in the Hertzsprung–Russell diagram (HRD). We estimate the effect of the offsets on bolometric corrections as a function of position in the HRD and use this for a brief discussion of their impact on the studies of stellar populations. A review of the literature shows that comparable discrepancies are mentioned in studies using other theoretical and empirical libraries.
Highlights
Stellar population studies based on the integrated spectra or colors of galaxies have a long history
While it may not be critical to characterize each galaxy in detail to study the average evolution of the stellar mass across cosmic time (e.g., Madau & Dickinson 2014; Moutard et al 2016), age and metallicity estimates become essential when studying the assembly of galaxy components; accurate interpretations of colors and spectral features are necessary to disentangle otherwise degenerate properties such as age, metallicity, and extinction, to obtain absolute rather than relative values for these quantities, or to constrain the stellar initial mass function based on integrated light
The spectral energy distributions (SEDs) for the parameters of DR2 The differences between empirical and theoretical energy distributions as measured by D (Eq (1)) display systematic trends as a function of effective temperature, surface gravity, and metallicity, and we have chosen to present them in HR-diagrams directly comparable to Fig. 1
Summary
Stellar population studies based on the integrated spectra or colors of galaxies have a long history. While it may not be critical to characterize each galaxy in detail to study the average evolution of the stellar mass across cosmic time (e.g., Madau & Dickinson 2014; Moutard et al 2016), age and metallicity estimates become essential when studying the assembly of galaxy components; accurate interpretations of colors and spectral features are necessary to disentangle otherwise degenerate properties such as age, metallicity, and extinction, to obtain absolute rather than relative values for these quantities, or to constrain the stellar initial mass function based on integrated light. The bolometric corrections associated with the SEDs determine the relative contributions of any type of star at any particular wavelength, and these contributions are key ingredients of the interpretation of the summed spectral features of the stellar population under scrutiny
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