Characterising the surface magnetic fields of T Tauri stars with high-resolution near-infrared spectroscopy

TL;DR

This study characterizes surface magnetic fields of 8 T Tauri stars using high-resolution near-IR spectroscopy, applying Bayesian Zeeman broadening models to measure magnetic field strengths and compare small-scale and large-scale magnetic fields.

Contribution

It introduces a Bayesian framework for modeling stellar magnetic fields from near-IR spectra and expands the sample of T Tauri stars with measured surface magnetic fields.

Findings

Magnetic field strengths range from 1.5 kG to 4.4 kG.

No significant rotational variation in magnetic field strength detected.

Small-scale magnetic fields are more homogeneous than large-scale fields.

Abstract

We aim to characterise the surface magnetic fields of a sample of 8 T Tauri stars from high-resolution near-IR spectroscopy. Some stars in our sample are known to be magnetic from previous spectroscopic or spectropolarimetric studies. Our goals are 1) to apply Zeeman broadening modelling to T Tauri stars with high-resolution data, 2) to expand the sample of stars with measured surface magnetic field strengths, 3) to investigate possible rotational or long-term magnetic variability by comparing spectral time series of given targets, and 4) to compare the magnetic field modulus <B> tracing small-scale magnetic fields to those of large-scale magnetic fields derived by Stokes V Zeeman Doppler Imaging. We modelled the Zeeman broadening of magnetically sensitive spectral lines in the near-IR K-band from high-resolution spectra by using magnetic spectrum synthesis based on realistic model atmospheres and by using different descriptions of the surface magnetic field. We developped a Bayesian framework that selects the complexity of the magnetic field prescription based on the information contained in the data. We obtain individual magnetic field measurements for each star in our sample using four different models. We find that the Bayesian Model 4 performs best in the range of magnetic fields measured on the sample (from 1.5 kG to 4.4 kG). We do not detect a strong rotational variation of <B> with a mean peak-to-peak variation of 0.3 kG. Our confidence intervals are of the same order of magnitude, which suggests that the Zeeman broadening is produced by a small-scale magnetic field homogeneously distributed over stellar surfaces. A comparison of our results with mean large-scale magnetic field measurements from Stokes V ZDI show different fractions of mean field strength being recovered, from 25-42% for relatively simple poloidal axisymmetric field topologies to 2-11% for more complex fields.