Origin of eclipsing time variations: Contributions of different modes of the dynamo-generated magnetic field

TL;DR

This study uses magnetohydrodynamical simulations to explore how different magnetic field modes influence eclipsing time variations in binary stars, revealing complex magnetic behaviors and their effects on stellar quadrupole moments.

Contribution

It provides new insights into the connection between magnetic field structures and ETVs, comparing dynamo models with simulations and discussing implications for observed binaries.

Findings

Complex magnetic fields lead to larger quadrupole moment variations.

Simulations show magnetic asymmetries modulate the quadrupole moment.

Results align with observations if tidal locking is not assumed.

Abstract

The possibility to detect circumbinary planets and to study stellar magnetic fields through eclipsing time variations (ETVs) in binary stars has sparked an increase of interest in this area of research. We revisit the connection between stellar magnetic fields and the gravitational quadrupole moment $Q_{xx}$ and compare different dynamo-generated ETV models with our simulations. We present magnetohydrodynamical simulations of solar mass stars with rotation periods of 8.3, 1.2, and 0.8 days and perform a detailed analysis of the magnetic and quadrupole moment using spherical harmonic decomposition. The extrema of $Q_{xx}$ are associated with changes in the magnetic field structure. This is evident in the simulation with a rotation period of 1.2 days. Its magnetic field has a more complex behavior than in the other models, as the large-scale nonaxisymmetric field dominates throughout the simulation and the axisymmetric component is predominantly hemispheric. This triggers variations in the density field that follow the magnetic field asymmetry with respect to the equator, affecting the $zz$ component of the inertia tensor, and thus modulating $Q_{xx}$. The magnetic field of the two other runs are less variable in time and more symmetric with respect to the equator, such that the variations in the density are weaker, and therefore only small variations in $Q_{xx}$ are seen. If interpreted via the classical Applegate mechanism (tidal locking), the quadrupole moment variations obtained in the current simulations are about two orders of magnitude below those deduced from observations of post-common-envelope binaries. However, if no tidal locking is assumed, our results are compatible with the observed ETVs.