# High-resolution spectroscopy of Boyajian's star during optical dimming   events

**Authors:** M. J. Mart\'inez Gonz\'alez, C. Gonz\'alez-Fern\'andez, A. Asensio, Ramos, H. Socas Navarro, C. Westendorp Plaza, T. S. Boyajian, J. T. Wright,, A. Collier Cameron, J. Gonz\'alez Hern\'andez, G. Holgado, G. M. Kennedy, T., Masseron, E. Molinari, J. Saario, S. Sim\'on-D\'iaz, and B. Toledo-Padr\'on

arXiv: 1812.06837 · 2019-04-10

## TL;DR

This study uses high-resolution spectroscopy to analyze Boyajian's star during dimming events, finding no evidence of interstellar or exocomet involvement and suggesting an occulting object causes the observed light curve dips.

## Contribution

First spectroscopic follow-up during dimming events of Boyajian's star, constraining hypotheses about occulting elements and star activity.

## Key findings

- Star's magnetism is not extreme.
- Surface spots, if any, are very small.
- Star's chromosphere is hotter than expected.

## Abstract

Boyajian's star is an apparently normal main sequence F-type star with a very unusual light curve. The dipping activity of the star, discovered during the Kepler mission, presents deep, asymmetric, and aperiodic events. Here we present high resolution spectroscopic follow-up during some dimming events recorded post-Kepler observations, from ground-based telescopes. We analise data from the HERMES, HARPS-N and FIES spectrographs to characterise the stellar atmosphere and to put some constraints on the hypotheses that have appeared in the literature concerning the occulting elements. The star's magnetism, if existing, is not extreme. The spots on the surface, if present, would occupy 0.02% of the area, at most. The chromosphere, irrespective of the epoch of observation, is hotter than the values expected from radiative equilibrium, meaning that the star has some degree of activity. We find no clear evidence of the interstellar medium nor exocoments being responsible for the dimmings of the light curve. However, we detect at 1-2 sigma level, a decrease of the radial velocity of the star during the first dip recorded after the \emph{\emph{Kepler}} observations. We claim the presence of an optically thick object with likely inclined and high impact parameter orbits that produces the observed Rossiter-McLaughlin effect.

## Full text

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## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/1812.06837/full.md

## References

46 references — full list in the complete paper: https://tomesphere.com/paper/1812.06837/full.md

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Source: https://tomesphere.com/paper/1812.06837