# Spectroscopy of Dwarf Stars Around the North Celestial Pole

**Authors:** \v{S}ar\=unas Mikolaitis, Gra\v{z}ina Tautvai\v{s}ien\.e, Arnas, Drazdauskas, Renata Minkevi\v{c}i\=ut\.e, Lukas Klebonas, Vilius Bagdonas,, Erika Pak\v{s}ien\.e, Rimvydas Janulis

arXiv: 1901.01082 · 2019-01-07

## TL;DR

This study provides high-resolution spectroscopic parameters for bright dwarf stars near the North Celestial Pole, aiding stellar characterization for upcoming space missions like TESS and PLATO, and confirms their galactic disk membership and metallicity gradients.

## Contribution

First spectroscopic atmospheric parameters for 73% of these stars, enhancing stellar data for exoplanet research and galactic structure studies.

## Key findings

- Most stars are in the thin disk of the Milky Way.
- Derived metallicity gradients support inside-out disk formation models.
- Results are consistent with recent spectral studies.

## Abstract

New space missions (e.g., NASA-TESS and ESA-PLATO) will perform an analysis of bright stars in large fields of the celestial sphere searching for extraterrestrial planets. Asteroseismic observations will search for exoplanet-hosting stars with solar-like oscillations. In order to achieve all the goals, a full characterization of the stellar objects is important. However, accurate atmospheric parameters are available for less than 30% of bright dwarf stars of the solar neighborhood. In this study we observed high-resolution (R = 60,000) spectra for all bright (V < 8 mag) and cooler than F5 spectral class dwarf stars in the northern-most field of the celestial sphere with radius of 20{\deg} from the {\alpha}(2000) = 161$^\circ$03 and {\delta}(2000) = 86$^\circ$60 that is a center of one of the preliminary ESO-PLATO fields. Spectroscopic atmospheric parameters were determined for 140 slowly rotating stars, for 73% of them for the first time. The majority (83%) of the investigated stars are in the TESS object lists and all of them are in the preliminary PLATO field. Our results have no systematic differences when compared with other recent studies. Comparing our results for 39 stars with previous high-resolution spectral determinations, we find only a 7 $\pm$ 73 K difference in effective temperatures, 0.02 $\pm$ 0.09 in log g, and -0.02 $\pm$ 0.09 dex in metallicities. We also determined basic kinematic and orbital parameters for this sample of stars. From the kinematical point of view, almost all our stars belong to the thin disk substructure of the Milky Way. The derived galactocentric metallicity gradient is -0.066 $\pm$ 0.024 dex/kpc (2.5{\sigma} significance) and the vertical metallicity gradient is -0.102 $\pm$ 0.099 dex/kpc (1{\sigma} significance) that comply with the latest inside-out thin disk formation models, including those with stellar migration taken into account.

## Full text

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## Figures

22 figures with captions in the complete paper: https://tomesphere.com/paper/1901.01082/full.md

## References

123 references — full list in the complete paper: https://tomesphere.com/paper/1901.01082/full.md

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Source: https://tomesphere.com/paper/1901.01082