Magnetism of Herbig Ae/Be stars

TL;DR

This paper reports the detection of organized magnetic fields in a small fraction of Herbig Ae/Be stars, providing insights into their magnetic properties and implications for star formation theories.

Contribution

It presents the first systematic detection and analysis of magnetic fields in Herbig Ae/Be stars, supporting the fossil field hypothesis and comparing pre-main sequence and main sequence magnetic properties.

Findings

9 magnetic Herbig Ae/Be stars detected

Magnetic fields have kG dipole components, stable over years

Magnetic incidence rate of about 7%, similar to main sequence stars

Abstract

Observations of magnetic fields of stars at the pre-main sequence phase can provide important new insights into the complex physics of the late stages of star formation. This is especially true at intermediate stellar masses, where magnetic fields are strong and globally organised, and therefore most amenable to direct study. Recent circularly-polarised spectroscopic observations of pre-main sequence Herbig Ae/Be stars have revealed the presence of organised magnetic fields in the photospheres of a small fraction of these objects. To date, 9 magnetic HAeBe stars have been detected, and those detections confirmed by repeated observations. The morphology and variability of their Stokes V signatures indicates that their magnetic fields have important dipole components of kG strength, and that the dipole is stable on timescales ofat least years. These magnetic stars exhibit a large range of stellar mass, from about 2-13 solar masses, and diverse rotational properties, with vsini from a few km/s to 200 km/s. Most magnetic HAeBe stars show approximately solar abundances; they clearly do not generally exhibit the strong and systematic peculiarities of the magnetic main sequence A and B type stars (the Ap/Bp stars). The observed fractional bulk incidence of magnetic HAeBe stars is about 7%, a value compatible with the incidence of magnetic intermediate-mass stars on the main sequence. This low incidence is at odds with formation scenarios generally involving magnetically-mediated accretion. The similarily between the magnetic properties of the pre-main sequence and main sequence intermediate-mass stars appears compatible with the hypothesis of a fossil origin of magnetism in these objects.