The SOFIA Massive (SOMA) star formation Q-band follow-up II. Hydrogen recombination lines towards high-mass protostars
Journal article, 2025
Context. Hydrogen recombination lines (HRLs) are valuable diagnostics of the physical conditions in ionized regions surrounding high-mass stars. Understanding these lines, including broadening mechanisms and intensity trends, can provide insights into HII region densities, temperatures, and kinematics.
Aims. This study aims to investigate the physical properties of ionized gas around massive protostars by analysing the HRLs (H alpha and H beta) in the Q band.
Methods. We carried out observations using the Yebes 40m radio telescope in the Q band (30.5-50 GHz) towards six high-mass protostars selected from the SOMA Survey (G45.12+0.13, G45.47+0.05, G28.20-0.05, G35.20-0.74, G19.08-0.29, and G31.28+0.06). The observed line profiles were analysed to assess broadening mechanisms, and electron densities and temperatures were derived. The results were compared with available Q-band data from the TianMa 65-m Radio Telescope (TMRT) that have been reported in the literature, and ALMA Band 1 (35-50 GHz) Science Verification observations towards Orion KL, analysed in this study.
Results. A total of eight H alpha (n = 51 to 58) and ten H beta (n = 64 to 73) lines were detected towards G45.12+0.13, G45.47+0.05, and G28.20-0.05; there were no detections in other sources. We derived electron densities of similar to 1-5 x 10(6) cm(-3) and temperatures of 8000-10 000 K for the sources. However, for Orion KL, we obtained an electron density one order of magnitude lower, while its temperature was found to be more similar. Interestingly, G45.12 and G28.20 show an increasing intensity trend with frequency for both H alpha and H beta transitions, contrary to the decreasing trend observed in Orion KL.
Conclusions. The line widths of the detected HRLs indicate contributions from both thermal and dynamical broadening, suggesting the presence of high-temperature ionized gas that is likely kinematically broadened (e.g. due to turbulence, outflows, rapid rotation, or stellar winds). Pressure broadening caused by electron density may also have a minor effect. We discuss different scenarios to explain the measured line widths of the HRLs. The contrasting intensity trends between the sources may reflect variations in local physical conditions or radiative transfer effects, highlighting the need for further investigation through higher-resolution observations and detailed modelling.
Aims. This study aims to investigate the physical properties of ionized gas around massive protostars by analysing the HRLs (H alpha and H beta) in the Q band.
Methods. We carried out observations using the Yebes 40m radio telescope in the Q band (30.5-50 GHz) towards six high-mass protostars selected from the SOMA Survey (G45.12+0.13, G45.47+0.05, G28.20-0.05, G35.20-0.74, G19.08-0.29, and G31.28+0.06). The observed line profiles were analysed to assess broadening mechanisms, and electron densities and temperatures were derived. The results were compared with available Q-band data from the TianMa 65-m Radio Telescope (TMRT) that have been reported in the literature, and ALMA Band 1 (35-50 GHz) Science Verification observations towards Orion KL, analysed in this study.
Results. A total of eight H alpha (n = 51 to 58) and ten H beta (n = 64 to 73) lines were detected towards G45.12+0.13, G45.47+0.05, and G28.20-0.05; there were no detections in other sources. We derived electron densities of similar to 1-5 x 10(6) cm(-3) and temperatures of 8000-10 000 K for the sources. However, for Orion KL, we obtained an electron density one order of magnitude lower, while its temperature was found to be more similar. Interestingly, G45.12 and G28.20 show an increasing intensity trend with frequency for both H alpha and H beta transitions, contrary to the decreasing trend observed in Orion KL.
Conclusions. The line widths of the detected HRLs indicate contributions from both thermal and dynamical broadening, suggesting the presence of high-temperature ionized gas that is likely kinematically broadened (e.g. due to turbulence, outflows, rapid rotation, or stellar winds). Pressure broadening caused by electron density may also have a minor effect. We discuss different scenarios to explain the measured line widths of the HRLs. The contrasting intensity trends between the sources may reflect variations in local physical conditions or radiative transfer effects, highlighting the need for further investigation through higher-resolution observations and detailed modelling.
stars: massive
line: identification
line: profiles
methods: data analysis
HII regions
astrochemistry
Author
Prasanta Gorai
University of Oslo
Kotomi Taniguchi
National Institutes of Natural Sciences
Jonathan Tan
Chalmers, Space, Earth and Environment
Miguel Gomez-Garrido
Observ Astron Nacl OAN IGN
Viviana Rosero
California Institute of Technology (Caltech)
Izaskun Jimenez-Serra
Spanish National Research Council (CSIC)
Yichen Zhang
Shanghai Jiao Tong University
Giuliana Cosentino
Institut de Radioastronomie Millimétrique (IRAM)
Chi-Yan Law
Arcetri Astrophysical Observatory
Ruben Fedriani
Spanish National Research Council (CSIC)
Gemma Busquet
University of Barcelona
Inst Estudis Espacials Catalunya IEEC
Brandt A. L. Gaches
University of Duisburg-Essen
Maryam Saberi
University of Oslo
Ankan Das
Institute of Astronomy Space and Earth Science
Astronomy and Astrophysics
0004-6361 (ISSN) 1432-0746 (eISSN)
Vol. 702 A107Subject Categories (SSIF 2025)
Astronomy, Astrophysics, and Cosmology
Meteorology and Atmospheric Sciences
DOI
10.1051/0004-6361/202556220