An update of the catalog of radial velocity standard stars from the APOGEE DR17

TL;DR

This paper updates the catalog of radial velocity standard stars from APOGEE DR17, providing a large, stable set of standards for calibrating large spectroscopic surveys and analyzing their systematic zero-point offsets.

Contribution

The paper presents a new, extensive catalog of over 46,000 RV standard stars with long-term stability, and assesses RV zero-point offsets for major spectroscopic surveys using this catalog.

Findings

Catalog contains 46,753 stable RV standard stars.

Median RV stability is better than 215 m/s over >200 days.

Estimated RV zero-point offsets for RAVE, LAMOST, GALAH, Gaia.

Abstract

We present an updated catalog of 46,753 radial velocity (RV) standard stars selected from the APOGEE DR17. These stars cover the Northern and Southern Hemispheres almost evenly, with 62% being red giants and 38% being main-sequence stars. These RV standard stars are stable on a baseline longer than 200 days (54% longer than one year and 10% longer than five years) with a median stability better than 215 m s$^{-1}$. The average observation number of those stars are 5 and each observation is required to have spectral-to-noise-ratio (SNR) greater than 50 and RV measurement error smaller than 500 m s$^{-1}$. Based on the new APOGEE RV standard star catalog, we have checked the RV zero points (RVZPs) for current large-scale stellar spectroscopic surveys including RAVE, LAMOST, GALAH and Gaia. By carefully analysis, we estimate their mean RVZP to be $+0.149$ km s$^{-1}$, $+4.574$ km s$^{-1}$ (for LRS), $-0.031$ km s$^{-1}$ and $+0.014$ km s$^{-1}$, respectively, for the four surveys. In the RAVE, LAMOST (for MRS), GALAH and Gaia surveys, RVZP exhibits systematic trend with stellar parameters (mainly [Fe/H], $T_{\rm{eff}}$, log $g$, $G_{\rm{BP}}-G_{\rm{RP}}$ and $G_{\rm{RVS}}$). The corrections of those small but clear RVZPs are of vital importances for these massive spectroscopic surveys in various studies that require extremely high radial velocity accuracies.