# The Mass of the White Dwarf Companion in the Self-Lensing Binary   KOI-3278: Einstein vs. Newton

**Authors:** Daniel A. Yahalomi, Yossi Shvartzvald, Eric Agol, Avi Shporer, David, W. Latham, Ethan Kruse, John M. Brewer, Lars A. Buchhave, Benjamin J. Fulton,, Andrew W. Howard, Howard Isaacson, Erik A. Petigura, Samuel N. Quinn

arXiv: 1904.11063 · 2019-07-31

## TL;DR

This study combines Einsteinian microlensing and Newtonian dynamics to precisely measure the white dwarf's mass in the KOI-3278 binary, enhancing understanding of white dwarf properties without relying on evolutionary models.

## Contribution

It presents a joint modeling approach that improves mass measurement accuracy and avoids assumptions about white dwarf mass-radius relations.

## Key findings

- White dwarf mass measured as approximately 0.525 solar masses.
- Joint model reduces uncertainty compared to individual methods.
- Consistent results between spectroscopic, microlensing, and dynamical analyses.

## Abstract

KOI-3278 is a self-lensing stellar binary consisting of a white-dwarf secondary orbiting a Sun-like primary star. Kruse and Agol (2014) noticed small periodic brightenings every 88.18 days in the Kepler photometry and interpreted these as the result of microlensing by a white dwarf with about 63$\%$ of the mass of the Sun. We obtained two sets of spectra for the primary that allowed us to derive three sets of spectroscopic estimates for its effective temperature, surface gravity, and metallicity for the first time. We used these values to update the Kruse and Agol (2014) Einsteinian microlensing model, resulting in a revised mass for the white dwarf of $0.539^{+0.022}_{-0.020} \, M_{\odot}$. The spectra also allowed us to determine radial velocities and derive orbital solutions, with good agreement between the two independent data sets. An independent Newtonian dynamical MCMC model of the combined velocities yielded a mass for the white dwarf of $0.5122^{+0.0057}_{-0.0058} \, M_{\odot}$. The nominal uncertainty for the Newtonian mass is about four times better than for the Einsteinian, $\pm 1.1\%$ vs. $\pm 4.1\%$ and the difference between the two mass determinations is $5.2 \%$. We then present a joint Einsteinian microlensing and Newtonian radial velocity model for KOI-3278, which yielded a mass for the white dwarf of $0.5250^{+0.0082}_{-0.0089} \, M_{\odot}$. This joint model does not rely on any white dwarf evolutionary models or assumptions on the white dwarf mass-radius relation. We discuss the benefits of a joint model of self-lensing binaries, and how future studies of these systems can provide insight into the mass-radius relation of white dwarfs.

## Full text

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## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/1904.11063/full.md

## References

51 references — full list in the complete paper: https://tomesphere.com/paper/1904.11063/full.md

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Source: https://tomesphere.com/paper/1904.11063