Applegate mechanism in post-common-envelope binaries: Investigating the role of rotation

F. H. Navarrete; D. R. G. Schleicher; J. Zamponi Fuentealba; M. Völschow

doi:10.1051/0004-6361/201732425

Issue		A&A Volume 615, July 2018


Article Number		A81
Number of page(s)		9
Section		Astrophysical processes
DOI		https://doi.org/10.1051/0004-6361/201732425
Published online		17 July 2018

A&A 615, A81 (2018)

Applegate mechanism in post-common-envelope binaries: Investigating the role of rotation

F. H. Navarrete¹, D. R. G. Schleicher¹, J. Zamponi Fuentealba¹ and M. Völschow²

¹ Departamento de Astronomía, Facultad de Ciencias Físicas y Matemáticas, Universidad de Concepción, Av. Esteban Iturra s/n, Barrio Universitario, Casilla 160-C, Chile
e-mail: felnavarrete@udec.cl
² Hamburger Sternwarte, Universität Hamburg, Gojenbergsweg 112, 21029 Hamburg, Germany

Received: 6 December 2017
Accepted: 12 March 2018

Abstract

Context. Eclipsing time variations are observed in many close binary systems. In particular, for several post-common-envelope binaries (PCEBs) that consist of a white dwarf and a main sequence star, the observed-minus-calculated (O–C) diagram suggests that real or apparent orbital period variations are driven by Jupiter-mass planets or as a result of magnetic activity, the so-called Applegate mechanism. The latter explains orbital period variations as a result of changes in the stellar quadrupole moment due to magnetic activity.

Aims. In this work we explore the feasibility of driving eclipsing time variations via the Applegate mechanism for a sample of PCEB systems, including a range of different rotation rates.

Methods. We used the MESA code to evolve 12 stars with different masses and rotation rates. We applied simple dynamo models to their radial profiles to investigate the scale at which the predicted activity cycle matches the observed modulation period, and quantifiy the uncertainty. We further calculated the required energies to drive the Applegate mechanism.

Results. We show that the Applegate mechanism is energetically feasible in 5 PCEB systems. In RX J2130.6+4710, it may be feasible as well considering the uncertainties. We note that these are the systems with the highest rotation rate compared to the critical rotation rate of the main-sequence star.

Conclusions. The results suggest that the ratio of physical to critical rotation rate in the main sequence star is an important indicator for the feasibility of Applegate’s mechanism, but exploring larger samples will be necessary to probe this hypothesis.

Key words: dynamo / stars: activity / binaries: close / stars: low-mass / stars: rotation

© ESO 2018

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