First detection of magnetic massive stars outside our galaxy

For the first time, magnetic fields have been detected in three massive, hot stars in our neighboring galaxies, the Large and Small Magellanic Clouds. While magnetic massive stars have already been detected in our own galaxy, the discovery of magnetism in the Magellanic Clouds is especially important because these galaxies have a strong population of young massive stars.
Magnetic Massive Stars:- For the first time, magnetic fields have been detected in three massive, hot stars in our neighboring galaxies, the Large and Small Magellanic Clouds.[AlphaGalileo]
Magnetic Massive Stars:- For the first time, magnetic fields have been detected in three massive, hot stars in our neighboring galaxies, the Large and Small Magellanic Clouds.[AlphaGalileo]

Magnetic Massive Stars:- For the first time, magnetic fields have been detected in three massive, hot stars in our neighboring galaxies, the Large and Small Magellanic Clouds. While magnetic massive stars have already been detected in our own galaxy, the discovery of magnetism in the Magellanic Clouds is especially important because these galaxies have a strong population of young massive stars. This provides a unique opportunity to study actively forming stars and the upper limit to the mass that a star can have and remain stable.

Notably, magnetism is considered to be a key component in massive star evolution, with far-reaching impact on their ultimate fate. It’s the massive stars with initially more than eight solar masses that leave behind neutron stars and black holes by the end of their evolution. Spectacular merging events of such compact remnant systems have been observed by gravitational wave observatories. Furthermore, theoretical studies propose a magnetic mechanism for the explosion of massive stars, relevant for gamma-ray bursts, x—ray flashes and supernovae.

"Studies of magnetic fields in massive stars in galaxies with young stellar populations provide crucial information on the role of magnetic fields in star formation in the early Universe with star-forming gas not polluted by metals" says Dr Swetlana Hubrig, from the Leibniz Institute for Astrophysics Potsdam (AIP) and first author of the study.

Stellar magnetic fields are measured using spectropolarimetry. For this circularly polarised starlight is recorded and the smallest changes in spectral lines are investigated. However, in order to achieve the necessary accuracy of the polarisation measurements, this method requires high quality data. "The method is extremely hungry for photons. This is a special challenge because even the brightest massive stars, which have more than eight solar masses, are relatively light-poor when observed in our neighbouring galaxies, the Large and the Small Magellanic Clouds," as Dr Silva Järvinen from the AIP explains. Because of these conditions, conventional high-resolution spectropolarimeters and smaller telescopes are unsuitable for such investigations. Therefore, the low-resolution spectropolarimeter FORS2 was used, which is mounted on one of the four 8-metre telescopes of the Very Large Telescope (VLT) of the European Southern Observatory (ESO).

Previous attempts to detect magnetic fields in massive stars outside our galaxy were unsuccessful. These measurements are complex and depend on several factors. The magnetic field that is measured with circular polarisation is called the longitudinal magnetic field, and it corresponds exclusively to the field component that points in the direction of the observer. It is similar to the light coming from a lighthouse, which is easy to see when the beam shines towards the observer. Because the magnetic field structure in massive stars is usually characterised by a global dipole with the axis inclined to the rotation axis, the strength of the longitudinal magnetic field can be zero at rotation phases when the observer is looking directly at the magnetic equator of the rotating star. The detectability of the polarisation signal also depends on the number of spectral features used to investigate the polarisation. The observation of a broader spectral region with a larger number of spectral features is preferable. In addition, longer exposure times are crucial for recording polarimetric spectra with a sufficiently high signal-to-noise ratio.

Taking these important factors into account, the team carried out spectropolarimetric observations of five massive stars in the Magellanic Clouds. In two presumably single stars with spectral characteristics typical for magnetic massive stars in our own Galaxy and in one actively interacting massive binary system (Cl*NGC346 SSN7) located within the core of the most massive star-forming region NGC346 in the Small Magellanic Cloud, they succeeded to detect magnetic fields of the order of kiloGauss. On our Sun's surface, such strong magnetic fields can only be detected in small highly magnetized regions - the sunspots. The reported magnetic field detections in the Magellanic Clouds present the first indication that massive star formation proceeds in galaxies with young stellar populations in a similar way as in our Galaxy. AlphaGalileo/SP

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