Consistent radial velocities of classical Cepheids from the cross-correlation technique

Abstract

Accurate radial velocities (v rad) of Cepheids are mandatory within the context of distance measurements via the Baade-Wesselink technique. The most common v rad derivation method consists in cross-correlating the observed spectrum with a binary template and measuring a velocity on the resulting profile. Yet for Cepheids, the spectral lines selected within the template as well as the way of fitting the cross-correlation function (CCF) have a significant impact on the measured v rad. We detail the steps to compute consistent Cepheid CCFs and v rad, and we characterise the impact of Cepheid spectral properties and v rad computation method on the resulting line profiles. We collected more than 3900 high-resolution spectra from seven different spectrographs of 64 classical Cepheids. These spectra were standardised through a single process on pre-defined wavelength ranges. We built six correlation templates selecting un-blended lines of different depths from a synthetic Cepheid spectrum, on three different wavelength ranges from 390 to 800 nm. Each spectrum was cross-correlated with these templates to build the corresponding CCFs. We derived a set of line profile observables as well as three different v rad measurements from each CCF. This study confirms that both the template wavelength range, its mean line depth and width, and the v rad computation method significantly impact the v rad. Deriving more robust Cepheid v rad time series require to minimise the asymmetry of the line profile and its impact on the v rad. Centroid v rad, that exhibit slightly smaller amplitudes but significantly smaller scatter than Gaussian or biGaussian v rad, should thus be favoured. Stronger lines are also less asymmetric and lead to more robust v rad than weaker lines.