Abstract Details

Name: Md Rashid
Affiliation: Indian Institute of Science (IISc), Balgalore
Conference ID: ASI2024_510
Title : A low radio frequency study of Orion: Indications of nonthermal emission
Authors and Co-Authors : Md Rashid1, Nirupam Roy1, Samir Choudhuri2
Abstract Type : Poster
Abstract Category : Stars, Interstellar Medium, and Astrochemistry in Milky Way
Abstract : The physical conditions of the interstellar medium (ISM) profoundly influence the star formation activity of galaxies. However, the exact role of the physical properties of ISM in regulating star formation is yet to be understood. Hence, it is crucial to constrain these properties through observations in the star-forming regions. The famous Orion H II region is one such region hosting a variety of objects, e.g., young star clusters, predominantly atomic photodissociation region (PDR), and layered ionized gases. Moreover, its proximity (414 ± 7 pc) makes it an ideal target for studying vital properties of the ISM in the star-forming region and physical processes happening in them. H II regions dominantly emit through thermal radiation mechanisms. However, a handful of H II regions are reported to emit nonthermal emissions. Recent studies have made efforts to explain such atypical nonthermal emissions through physical models. However, such observational results are relatively new and yet to be understood clearly. Using the enhanced capabilities of the upgraded Giant Metrewave Radio Telescope (uGMRT), we have studied the ISM in the Orion region. In this talk, I will present the results of the wide-band observations of the Orion nebula at unique low-frequency bands of uGMRT. From deep continuum images of band-3 (300 MHz – 500 MHz) and band-4 (635 MHz – 735MHz) of uGMRT, we have produced a reliable spectral index map. We are reporting indications of nonthermal emission from some parts of the Orion region. To establish the reliability of the spectral index map, we are also validating the reliability of the spectral map produced through simulated data of extended emission for uGMRT. I will also discuss possible physical scenarios and mechanisms that may explain this new finding.