Magnetic field topology and chemical spot distributions in the extreme Ap star HD 75049

Kochukhov, O.; Rusomarov, N.; Valenti, Jeff A.; Stempels, H. C.; Snik, Frans; Rodenhuis, M.; Piskunov, Nikolai; Makaganiuk, V.; Keller, Christoph U.; Johns-Krull, C. M.

doi:10.1051/0004-6361/201425065

Cited by 30 publications

(29 citation statements)

References 49 publications

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“…This situation is very different from the behaviour of massive, earlytype stars with pure dipole-like fossil fields for which simple global magnetic field models are able to simultaneously reproduce both polarisation and intensity magnetic observables (e.g. Landstreet & Mathys 2000;Kochukhov et al 2015).…”

Section: The Global and Total Magnetic Fields Of M Dwarfsmentioning

confidence: 84%

Magnetic Field of the Eclipsing M-dwarf Binary YY Gem

Kochukhov

Shulyak

2019

ApJ

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YY Gem is a short-period eclipsing binary system containing two nearly identical, rapidly rotating, very active early-M dwarfs. This binary represents an important benchmark system for calibrating empirical relations between fundamental properties of low-mass stars and for testing theories of interior structure and evolution of these objects. Both components of YY Gem exhibit inflated radii, which has been attributed to poorly understood magnetic activity effects. Despite a long history of magnetic activity studies of this system no direct magnetic field measurements have been made for it. Here we present a comprehensive characterisation of the surface magnetic field in both components of YY Gem. We reconstructed the global field topologies with the help of a tomographic inversion technique applied to high-resolution spectropolarimetric data. This analysis revealed moderately complex global fields with a typical strength of 200-300 G and anti-aligned dipolar components. A complementary Zeeman intensification analysis of the disentangled intensity spectra showed that the total mean field strength reaches 3.2-3.4 kG in both components of YY Gem. We used these results together with other recent magnetic field measurements of M dwarfs to investigate the relation between the global and small-scale fields in these stars. We also assessed predictions of competing magnetoconvection interior structure models developed for YY Gem, finding that only one of them anticipated the surface field strength compatible with our observations. Results of our star spot mapping of YY Gem do not support the alternative family of theoretical stellar models which attempts to explain the radii inflation by postulating a large spot filling factor.

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Section: The Global and Total Magnetic Fields Of M Dwarfsmentioning

confidence: 84%

Magnetic Field of the Eclipsing M-dwarf Binary YY Gem

Kochukhov

Shulyak

2019

ApJ

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“…We performed this task with the MDI code invers10 introduced by and . In this study, we closely follow already established methodological practices that have been used in recent MDI studies (e.g., Rusomarov et al 2015;Kochukhov et al 2015).…”

Section: Methodsmentioning

confidence: 99%

Magnetic Doppler imaging of the chemically peculiar star HD 125248

Rusomarov

Kochukhov

Ryabchikova

et al. 2016

A&A

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Context. Intermediate-mass, chemically peculiar stars with strong magnetic fields provide an excellent opportunity to study the topology of their surface magnetic fields and the interplay between magnetic geometries and abundance inhomogeneities in the atmospheres of these stars. Aims. We reconstruct detailed maps of the surface magnetic field and abundance distributions for the magnetic Ap star HD 125248. Methods. We performed the analysis based on phase-resolved, four Stokes parameter spectropolarimetric observations obtained with the HARPSpol instrument. These data were interpreted with the help of magnetic Doppler imaging techniques and model atmospheres taking the effects of strong magnetic fields and nonsolar chemical composition into account. Results. We improved the atmospheric parameters of the star, T eff = 9850 ± 250 K and log g = 4.05 ± 0.10. We performed detailed abundance analysis, which confirmed that HD 125248 has abundances typical of other Ap stars, and discovered significant vertical stratification effects for the Fe ii and Cr ii ions. We computed LSD Stokes profiles using several line masks corresponding to Fepeak and rare earth elements, and studied their behavior with rotational phase. Combining previous longitudinal field measurements with our own observations, we improved the rotational period of the star P rot = 9.29558 ± 0.00006 d. Magnetic Doppler imaging of HD 125248 showed that its magnetic field is mostly poloidal and quasi-dipolar with two large spots of different polarity and field strength. The chemical maps of Fe, Cr, Ce, Nd, Gd, and Ti show abundance contrasts of 0.9-3.5 dex. Among these elements, the Fe abundance map does not show high-contrast features. Cr is overabundant around the negative magnetic pole and has 3.5 dex abundance range. The rare earth elements and Ti are overabundant near the positive magnetic pole. Conclusions. The magnetic field of HD 125248 has strong deviations from the classical oblique dipole field geometry. A comparison of the magnetic field topology of HD 125248 with the results derived for other stars using four Stokes magnetic Doppler imaging suggests evidence that the field topology becomes simpler with increasing age. The abundance maps show weak correlation with magnetic field geometry, but they do not agree with the theoretical atomic diffusion calculations, which predict element accumulation in the horizontal field regions.

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“…The chemically peculiar Ap/Bp stars have their distinct chemical surface abundance to this particular effect (e.g., Alecian & Stift 2017). Moreover, these magnetic fields can lead to surface abundance inhomogeneities (i.e., spots) by suppressing thermal convection at the stellar surface, as seen from tomographic images (e.g., HD 75049; Kochukhov et al 2015), the rotational modulation of absorption lines (e.g., HR 5907; Grunhut et al 2012) or from the photometric brightness (e.g., σ Ori E; Oksala et al 2015). A&A 605, A104 (2017) In addition, the stellar wind is affected by the large-scale magnetic field, as ionized ejected mass follows the magnetic field lines, leading to typical observational signatures.…”

Section: The Effect Of Magnetism In Early-type Starsmentioning

confidence: 99%

Magnetic characterization of the SPB/β Cep hybrid pulsator HD 43317

Buysschaert

Neiner

Briquet

et al. 2017

A&A

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Large-scale magnetic fields at the surface of massive stars do not only influence the outer-most layers of the star, but also have consequences for the deep interior, only observationally accessible through asteroseismology. We performed a detailed characterization of the dipolar magnetic field at the surface of the B3.5V star HD 43317, a SPB/β Cep hybrid pulsator, by studying the rotationally modulated magnetic field of archival and new Narval spectropolarimetry. Additionally, we employed a grid-based approach to compare the Zeeman signatures with model profiles. By studying the rotational modulation of the He lines in both the Narval and HARPS spectroscopy caused by co-rotating surface abundance inhomogeneities, we updated the rotation period to 0.897673 ± 0.000004 d. The inclination angle between the rotation axis and the observer's line of sight remains ill-defined, because of the low level of variability in Stokes V and deformations in the intensity profiles by stellar pulsation modes. The obliquity angle between the rotation and magnetic axes is constrained to β ∈ [67, 90] • , and the strength of the dipolar magnetic field is of the order of 1 kG to 1.5 kG. This magnetic field at the stellar surface is sufficiently strong to warrant a uniformly rotating radiative envelope, causing less convective core overshooting, which should be visible in future forward seismic modeling.

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Magnetic field topology and chemical spot distributions in the extreme Ap star HD 75049

Cited by 30 publications

References 49 publications

Magnetic Field of the Eclipsing M-dwarf Binary YY Gem

Magnetic Field of the Eclipsing M-dwarf Binary YY Gem

Magnetic Doppler imaging of the chemically peculiar star HD 125248

Magnetic characterization of the SPB/β Cep hybrid pulsator HD 43317

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