Empirical Bolometric Correction and Zero-Point Constants of Visual Magnitudes from High-Resolution Spectra

Abstract

A method of obtaining bolometric corrections (BC V) from observed high-resolution, high-S/N spectra is described. The method is applied to spectra of 128 stars collected from the literature with well-determined effective temperatures (T eff) with Sλ(V) transparency profiles of Bessell and Landolt. Computed BC V are found accurate within several milimagnitudes and the effect of different Sλ(V) is found to be no more than 0.015 mag. Measured visual to bolometric ratio (L V/L) from the sample spectra and classically determined BC V from bolometric (M Bol) and visual (M V) absolute magnitudes helped us to determine the zero-point constant (C 2) of the BC V scale. Determined C 2 for each star for each Sλ(V) profile revealed C 2 = 2.36530.0067 mag if Sλ(V) profile of Bessell is used, and C 2 = 2.38260.0076 mag if Sλ(V) profile of Landolt is used. Expanding C Bol = 71.197425 ... mag and c Bol = -18.997351 ... mag announced by IAU2015GARB2, and using definition of C 2 = C Bol-C V = c Bol-c V, where capital C is for the absolute and small c is for the apparent, subscripts indicating bolometric and visual, the zero-point constants: C V = 68.83210.0067 mag and c V = -21.36270.0067 mag, if L V and are in SI units, were determined corresponding to Sλ(V) of Bessell. The zero-point constants corresponding to Sλ(V) of Landolt are smaller, but the difference is not more than 0.02 mag. Typical and limiting accuracies for predicting a stellar luminosity from an apparent magnitude and a distance are analyzed.

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