A search for the favored hyperfine transition of a 6.7 GHz methanol maser line
Journal article, 2025

Context. The polarized emission of astrophysical masers, especially OH and CH3OH lines, is an effective tool to study the magnetic field in high-mass star-forming regions. The magnetic field strength measurement via the Zeeman effect of OH maser emission is well established, but that of the CH3OH maser emission is still under debate because of its complex hyperfine structure. Aims. We aim to identify the dominating hyperfine transition of the Class II 6.7 GHz CH3OH maser emission by comparing the magnetic field strength measured with the 6.0 GHz excited OH maser emission and the Zeeman splitting of the CH3OH maser emission. Methods. We used quasi-simultaneous European VLBI Network observations of the two maser emissions at 6.035 GHz (excited OH maser) and 6.668 GHz (CH3OH maser) toward two well-known high-mass young stellar objects: G69.540-0.976 (ON 1) and G81.871+0.781 (W75N). The observations were performed in full polarimetric mode and in phase-referencing mode to couple the maser features of the two maser emissions in each source. Results. We detected linearly and circularly polarized emission in both maser transitions and high-mass young stellar objects. Specifically, we measured the magnetic field strength in twelve and five excited OH maser features toward ON 1 and W75N, respectively, and the Zeeman splitting of the CH3OH maser spectra in one and three maser features toward ON 1 and W75N, respectively. We determined that the two maser emissions likely probe the same magnetic field but at different densities. Indeed, a direct comparison of the magnetic field strength and the Zeeman splitting as measured with the excited OH and CH3OH maser spots, respectively, provided values of the Zeeman splitting coefficient (αZ) for the 6.7 GHz CH3OH maser that do not match with any of the table values present in the literature. Conclusions. We are not able to uniquely identify the dominating hyperfine transition; however, through density considerations we can narrow the choice down to three hyperfine transitions: 3→4, 6→7A, and 7→8. Furthermore, we support the previously proposed idea that the favored hyperfine transition is not always the same, but that in different high-mass young stellar objects, the dominating one can be any of these three hyperfine transitions.

stars: massive

stars: formation

polarization

ISM: molecules

masers

ISM: magnetic fields

Author

A. Kobak

Nicolaus Copernicus University (SGMK)

G. Surcis

Istituto nazionale di astrofisica (INAF)

A. Bartkiewicz

Nicolaus Copernicus University (SGMK)

Wouter Vlemmings

Chalmers, Space, Earth and Environment, Astronomy and Plasmaphysics

M. Szymczak

Nicolaus Copernicus University (SGMK)

Astronomy and Astrophysics

0004-6361 (ISSN) 1432-0746 (eISSN)

Vol. 701 A101

Subject Categories (SSIF 2025)

Fusion, Plasma and Space Physics

Astronomy, Astrophysics, and Cosmology

DOI

10.1051/0004-6361/202555576

More information

Latest update

9/26/2025