# Hint of curvature in the orbital motion of the exoplanet 51 Eridani b   using 3 years of VLT/SPHERE monitoring

**Authors:** A.-L. Maire, L. Rodet, F. Cantalloube, R. Galicher, W. Brandner, S., Messina, C. Lazzoni, D. Mesa, D. Melnick, J. Carson, M. Samland, B. A., Biller, A. Boccaletti, Z. Wahhaj, H. Beust, M. Bonnefoy, G. Chauvin, S., Desidera, M. Langlois, T. Henning, M. Janson, J. Olofsson, D. Rouan, F., M\'enard, A.-M. Lagrange, R. Gratton, A. Vigan, M. R. Meyer, A. Cheetham,, J.-L. Beuzit, K. Dohlen, H. Avenhaus, M. Bonavita, R. Claudi, M. Cudel, S., Daemgen, V. D'Orazi, C. Fontanive, J. Hagelberg, H. Le Coroller, C. Perrot,, E. Rickman, T. Schmidt, E. Sissa, S. Udry, A. Zurlo, L. Abe, A. Orign\'e, F., Rigal, G. Rousset, A. Roux, L. Weber

arXiv: 1903.07620 · 2019-04-24

## TL;DR

This study uses three years of VLT/SPHERE data to suggest a potential curvature in the orbit of exoplanet 51 Eridani b, providing improved orbital constraints and hints of orbital dynamics.

## Contribution

First direct astrometric monitoring over three years indicating possible orbital curvature and refined orbital parameters of 51 Eridani b.

## Key findings

- Detected orbital motion with a decreasing separation of ~10 mas.
- Suggested an orbital period of approximately 32 years.
- Indicated possible alignment or misalignment within 18 degrees of the star-planet system.

## Abstract

Context. The 51 Eridani system harbors a complex architecture with its primary star forming a hierarchical system with the binary GJ 3305AB at a projected separation of 2000 au, a giant planet orbiting the primary star at 13 au, and a low-mass debris disk around the primary star with possibly a cold component and a warm component inferred from the spectral energy distribution. Aims. We aim to better constrain the orbital parameters of the known giant planet. Methods. We monitored the system over three years from 2015 to 2018 with the VLT/SPHERE exoplanet imaging instrument. Results. We measure an orbital motion for the planet of ~130 mas with a slightly decreasing separation (~10 mas) and find a hint of curvature. This potential curvature is further supported at 3$\sigma$ significance when including literature GPI astrometry corrected for calibration systematics. Fits of the SPHERE and GPI data using three complementary approaches provide broadly similar results. The data suggest an orbital period of 32$^{+17}_{-9}$ yr (i.e. 12$^{+4}_{-2}$ au in semi-major axis), an inclination of 133$^{+14}_{-7}$ deg, an eccentricity of 0.45$^{+0.10}_{-0.15}$, and an argument of periastron passage of 87$^{+34}_{-30}$ deg [mod 180 deg]. The time at periastron passage and the longitude of node exhibit bimodal distributions because we do not detect yet if the planet is accelerating or decelerating along its orbit. Given the inclinations of the planet's orbit and of the stellar rotation axis (134-144 deg), we infer alignment or misalignment within 18 deg for the star-planet spin-orbit. Further astrometric monitoring in the next 3-4 years is required to confirm at a higher significance the curvature in the planet's motion, determine if the planet is accelerating or decelerating on its orbit, and further constrain its orbital parameters and the star-planet spin-orbit.

## Full text

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## Figures

30 figures with captions in the complete paper: https://tomesphere.com/paper/1903.07620/full.md

## References

80 references — full list in the complete paper: https://tomesphere.com/paper/1903.07620/full.md

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Source: https://tomesphere.com/paper/1903.07620