A photospheric and chromospheric activity analysis of the quiescent retrograde-planet host $\nu$ Octantis A

TL;DR

This study investigates the activity of $ u$ Octantis A through spectroscopic analysis, providing evidence that supports the existence of a retrograde planet despite challenges to traditional planet formation theories.

Contribution

First large-scale chromospheric activity survey of $ u$ Octantis A, combining multiple spectral indices and line-depth ratios to assess stellar activity and support the planetary hypothesis.

Findings

No significant RV-correlated variability detected.

Temperature variations of only ±4 K found from line-depth ratios.

Ca II H-line and H α indices analyzed with improved error modeling.

Abstract

The single-lined spectroscopic binary $\nu$ Octantis provided evidence of the first conjectured circumstellar planet demanding an orbit retrograde to the stellar orbits. The planet-like behaviour is now based on 1437 radial velocities (RVs) acquired from 2001 to 2013. $\nu$ Oct's semimajor axis is only 2.6 AU with the candidate planet orbiting $\nu$ Oct A about midway between. These details seriously challenge our understanding of planet formation and our decisive modelling of orbit reconfiguration and stability scenarios. However, all non-planetary explanations are also inconsistent with numerous qualitative and quantitative tests including previous spectroscopic studies of bisectors and line-depth ratios, photometry from Hipparcos and the more recent space missions TESS and GAIA (whose increased parallax classifies $\nu$ Oct A closer still to a subgiant ~ K1 IV). We conducted the first large survey of $\nu$ Oct A's chromosphere: 198 Ca II H-line and 1160 H $\alpha$ indices using spectra from a previous RV campaign (2009-2013). We also acquired 135 spectra (2018-2020) primarily used for additional line-depth ratios, which are extremely sensitive to the photosphere's temperature. We found no significant RV-correlated variability. Our line-depth ratios indicate temperature variations of only $\pm$ 4 K, as achieved previously. Our atypical Ca II analysis models the indices in terms of S/N and includes covariance significantly in their errors. The H $\alpha$ indices have a quasi-periodic variability which we demonstrate is due to telluric lines. Our new evidence provides further multiple arguments realistically only in favor of the planet.