# The Sirius System and its Astrophysical Puzzles: Hubble Space Telescope   and Ground-Based Astrometry

**Authors:** Howard E. Bond (1, 2), Gail H. Schaefer (3), Ronald L. Gilliland (1,, 2), Jay B. Holberg (4), Brian D. Mason (5), Irving W. Lindenblad (5), Miranda, Seitz-McLeese (5), W. David Arnett (6), Pierre Demarque (7), Federico Spada, (8), Patrick A. Young (9), Martin A. Barstow (10), Matthew R. Burleigh (10),, and Donald Gudehus (11) ((1) Penn State Univ., (2) STScI, (3) CHARA Array,, (4) LPL, Univ. of Arizona, (5) US Naval Obs., (6) Steward Obs., Univ. of, Arizona, (7) Yale Univ., (8) Leibniz Institute Potsdam, (9) Arizona State, Univ., (10) Univ. of Leicester, (11) Georgia State Univ)

arXiv: 1703.10625 · 2017-05-24

## TL;DR

This study uses two decades of Hubble and historical data to precisely determine the orbital and physical parameters of the Sirius binary system, testing stellar evolution theories and ruling out unseen companions.

## Contribution

It provides the most accurate orbital elements and masses for Sirius A and B, confirms WD cooling models, and explores the system's evolutionary history and astrophysical puzzles.

## Key findings

- Dynamical masses of Sirius A and B are precisely measured.
- HST astrometry rules out third bodies down to 15-25 Mjup.
- Sirius B's position matches WD cooling and mass-radius models.

## Abstract

Sirius, the seventh-nearest stellar system, is a visual binary containing the metallic-line A1 V star Sirius A, brightest star in the sky, orbited in a 50.13-year period by Sirius B, the brightest and nearest white dwarf (WD). Using images obtained over nearly two decades with the Hubble Space Telescope (HST), along with photographic observations covering almost 20 years, and nearly 2300 historical measurements dating back to the 19th century, we determine precise orbital elements for the visual binary. Combined with the parallax and the motion of the A component, these elements yield dynamical masses of 2.063+/-0.023 Msun and 1.018+/-0.011 Msun for Sirius A and B, respectively. Our precise HST astrometry rules out third bodies orbiting either star in the system, down to masses of ~15-25 Mjup. The location of Sirius B in the H-R diagram is in excellent agreement with theoretical cooling tracks for WDs of its dynamical mass, and implies a cooling age of ~126 Myr. The position of Sirius B in the mass-radius plane is also consistent with WD theory, assuming a carbon-oxygen core. Including the pre-WD evolutionary timescale of the assumed progenitor, the total age of Sirius B is about 228+/-10 Myr. We calculated evolutionary tracks for stars with the dynamical mass of Sirius A, using two independent codes. We find it necessary to assume a slightly sub-solar metallicity, of about 0.85 Zsun, to fit its location in the luminosity-radius plane. The age of Sirius A based on these models is about 237-247 Myr, with uncertainties of +/-15 Myr, consistent with that of the WD companion. We discuss astrophysical puzzles presented by the Sirius system, including the probability that the two stars must have interacted in the past, even though there is no direct evidence for this, and the orbital eccentricity remains high.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1703.10625/full.md

## Figures

23 figures with captions in the complete paper: https://tomesphere.com/paper/1703.10625/full.md

## References

179 references — full list in the complete paper: https://tomesphere.com/paper/1703.10625/full.md

---
Source: https://tomesphere.com/paper/1703.10625