Manasi Saraf Joshi
Pune, 30 April 2021: Using the upgraded Giant Meterwave Radio Telescope (uGMRT), scientists from the National Centre for Radio Astrophysics of the Tata Institute of Fundamental Research (NCRA-TIFR) Pune determined that AT 2018 cow, the first of a newly discovered class of cosmic explosions, has an extremely patchy environment.
The paper (https://iopscience.iop.org/
The Fast Blue Optical Transient (FBOT) AT2018cow was discovered on 16 June 2018 at a distance of about 215 million light-years, the “cow” showed luminosities much greater than that of normal supernovae. Prof. Poonam Chandra (NCRA-TIFR) and A J Nayana carried out radio observations of AT 2018cow with the uGMRT to determine the properties of its extended environment and emission region. “Our study has tremendously benefited from the unique low-frequency capabilities of the uGMRT. The uGMRT observations of the “cow” played a unique role in finding the non-uniform density around this explosion”, says Nayana.
What is FBOT?
Sources like AT 2018cow release an enormous amount of energy, nonetheless fade extremely rapidly. This along with their extremely blue color has led to them being called FBOTs for Fast Blue Optical Transients. This is the first observational evidence of inhomogeneous emission from an FBOT. The origins of FBOTs are still under debate, but proposed models include explosion of a massive star, collision of an accreting neutron star and a star, merger of two white dwarfs, etc.
The FBOTs are difficult to find since they appear and vanish in the sky very quickly. However, several of them have been discovered in the past few years via the two recent advents of surveys that scan the sky almost on a daily basis. FBOTs that also emit in the radio are doubly rare but are particularly interesting because radio observations help one to determine the properties of the environments of these explosions and their progenitors.
Nayana added, “Our work provides the first observational evidence of inhomogeneous emission from an FBOT. The density of the material around this explosion falls drastically around 0.1 light-years from the transient. This indicates that the progenitor star of AT2018cow was shedding mass much faster towards its end of life.”
Aim behind the study
The longer one can observe the post-explosion emission, the more distance the material that was ejected during the explosion has traveled. This allows one to study the large scale environment of the source. Nayana and Prof. Chandra have been observing the “cow” for ∼ 2 years with the uGMRT to understand its properties.
“This is the first FBOT seen for this long at low radio frequencies and the uGMRT data gave crucial information about the environment of this transient”, Nayana said.
Prof Chandra explains, “This is the beauty of low-frequency radio observations. One gets to trace the footprints of the progenitor system much before it exploded”.
It is interesting that the material from the explosion is moving with speed greater than 20% speed of light even after ∼ 257 days post-explosion, without any deceleration”.
While the origin of FBOTs is still under debate, detailed radio observations can give hints about various physical parameters of these events like the speed of the material that came out of this explosion, the magnetic field strength, the rate by which the progenitor system sheds its mass before the explosion, etc. The uGMRT observations of the “cow” suggest that the progenitor erupted its material ∼ 100 times faster during the years close to its end-of-life compared to ∼ 23 years before the explosion. Also, AT2018cow showed in homogeneities in the radio-emitting region whereas the other two radio bright FBOTs did not show these properties, making the “cow” unique in the group.
“Observations of more FBOTs with the uGMRT will give information about their environments and progenitors to develop a comprehensive picture of the properties of these intriguing transients”, says Nayana.
The GMRT is an array of thirty 45-m antennas spread over a 25 sq-km area in Khodad village, Narayangaon (Pune district), India, built and operated by NCRA-TIFR, Pune. Currently, it is one of the most sensitive low-frequency radio telescopes in the world.Follow Punekar News: