Project VeSElkA: abundance analysis of chemical species in HD 41076 and HD 148330

Monthly Notices of the Royal Astronomical Society

2018

Project VeSElkA (Vertical Stratification of Element Abundances) has been initiated with the aim to detect and study the vertical stratification of element abundances in the atmosphere of chemically peculiar stars. Abundance stratification occurs in hydrodynamically stable stellar atmospheres due to the migration of the elements caused by atomic diffusion. Two HgMn stars, HD 53929 and HD 63975 were selected from the VeSElkA sample and analysed with the aim to detect some abundance peculiarities employing the ZEEMAN2 code. We present the results of abundance analysis of HD 53929 and HD 63975 observed recently with the spectropolarimeter ESPaDOnS at Canada-France-Hawaii Telescope. Evidence of phosphorus vertical stratification was detected in the atmosphere of these two stars. In both cases, phosphorus abundance increases strongly towards the superficial layers. The strong overabundance of Mn found in stellar atmosphere of both stars confirms that they are HgMn type stars.

Section: Analysis Methodsmentioning

confidence: 99%

Section: Vertical Abundance Stratificationmentioning

confidence: 99%

Project VeSElkA: results of abundance analysis for HD 53929 and HD 63975

N'Diaye

Leblanc

Monthly Notices of the Royal Astronomical Society

2018

“…These spectra were reduced using the dedicated software package Libre-ESpRIT (Donati et al 1997), which yields both the Stokes I spectrum and the Stokes V circular polarisation spectrum. The Stokes I spectra were normalised using the same procedure as in Khalack et al (2017); -one spectrum recorded with the Ultraviolet and Visible Echelle Spectrograph (UVES) fed by Unit Telescope 2 (UT2) of the ESO Very Large Telescope (VLT), retrieved from the ESO Archive; -and eight spectra recorded with the High Accuracy Radial velocity Planet Searcher (HARPS) fed by the ESO 3.6-m telescope, retrieved from the ESO Archive. One of these spectra was obtained with the polarimetric mode of HARPS (HARPSpol; Piskunov et al 2011) and is further discussed in Sect.…”

Section: Mean Magnetic Field Modulusmentioning

confidence: 99%

The 10.5 year rotation period of the strongly magnetic rapidly oscillating Ap star HD 166473

Mathys

Landstreet

2020

A&A

Self Cite

Context. How magnetic fields contribute to the differentiation of the rotation rates of the Ap stars and affect the occurrence of nonradial pulsation in some of them are important open questions. Valuable insight can be gained into these questions by studying some of the most extreme examples of the processes at play. The super-slowly rotating rapidly oscillating Ap (roAp) star HD 166473 is such an example. Aims. We performed the first accurate determination of its rotation period, P rot = (3836 ± 30) d, from the analysis of 56 measurements of the mean magnetic field modulus B based on high-resolution spectra acquired between 1992 and 2019 at various observatories and with various instrumental configurations. Methods. We complemented this analysis with the consideration of an inhomogeneous set of 21 determinations of the mean longitudinal magnetic field B z spanning the same time interval.Results. This makes HD 166473 one of only four Ap stars with a period longer than 10 years for which magnetic field measurements have been obtained over more than a full cycle. The variation curves of B and of B z are well approximated by cosine waves. The magnetic field of HD 166473 only seems to deviate slightly from axisymmetry, but it definitely involves a considerable non-dipolar component.Conclusions. Among the stars with rotation periods longer than 1000 d for which magnetic field measurements with full phase coverage are available, HD 166473 has the strongest field. Its magnetic field is also one of the strongest known among roAp stars. Overall, the magnetic properties of HD 166473 do not seem fundamentally distinct from those of the faster-rotating Ap stars. However, considering as a group the eight Ap stars that have accuractely determined periods longer than 1000 d and whose magnetic variations have been characterised over a full cycle suggests that the angles between their magnetic and rotation axes tend to be systematically large.

“…Specifically, in this study we use the grids of synthetic fluxes 6 simulated by Husser et al (2013) for models with different metallicities and abundances of the α-elements (O, Ne, Mg, Si, S, Ar, Ca, and Ti) employing version 16 7 of the PHOENIX code (Hauschildt & Baron 1999). These grids were computed with a spectral resolution of R = 500 000, which we reduced to R = 50 000 during their transformation to the format read by the FITSB2 code (Khalack et al 2017). This latter resolution is close to the spectral resolution of FEROS (see Section 2).…”

Section: Analysis Of Balmer Line Profilesmentioning

confidence: 99%

Rotational and pulsational variability in the TESS light curve of HD 27463

Monthly Notices of the Royal Astronomical Society

Lovekin

Bowman

et al. 2019

The new photometric data on pulsating Ap star HD 27463 obtained recently with the Transiting Exoplanet Survey Satellite (TESS) are analysed to search for variability. Our analysis shows that HD 27463 exhibits two types of photometric variability. The low-frequency variability with the period P = 2.834 274 ± 0.000 008 d can be explained in terms of axial stellar rotation assuming the oblique magnetic rotator model and presence of surface abundance/brightness spots, while the detected high-frequency variations are characteristics of δ Scuti pulsations. From the analysis of Balmer line profiles visible in two FEROS spectra of HD 27463 we have derived its effective temperature and surface gravity, finding values that are close to those published for this star in the TESS Input Catalogue (TIC). Knowing the rotation period and the v sin i value estimated from the fitting of Balmer line profiles we found that the rotational axis is inclined to the line of sight with an angle of $i=33\pm 8\deg$. Our best-fitting model of the observed pulsation modes results in an overshoot parameter value fov = 0.014 and values of global stellar parameters that are in good agreement with the data reported in the TIC and with the data derived from fitting Balmer line profiles. This model indicates an age of 5.0 ± 0.4 × 108 yr, which corresponds to a core hydrogen fraction of 0.33.