When astronomers noticed a strong gamma-ray burst (GRB) in October 2019, the most certainly clarification was that it was produced by a large dying star in a distant galaxy exploding in a supernova. But information from subsequent observations confirmed that the burst originated with the collision of stars (or their remnants) in a densely packed space close to the supermassive black gap of an historical galaxy, in response to a brand new paper revealed in the journal Nature Astronomy. Such a uncommon occasion has been hypothesized, however that is the primary observational proof for one.
As we have reported beforehand, gamma-ray bursts are extraordinarily high-energy explosions in distant galaxies lasting between mere milliseconds to a number of hours. There are two courses of gamma-ray bursts. Most (70 %) are lengthy bursts lasting greater than two seconds, typically with a shiny afterglow. These are normally linked to galaxies with fast star formation. Astronomers suppose that lengthy bursts are tied to the deaths of huge stars collapsing to kind a neutron star or black gap (or, alternatively, a newly fashioned magnetar). The child black gap would produce jets of extremely energetic particles shifting close to the velocity of sunshine, highly effective sufficient to pierce by the stays of the progenitor star, emitting X-rays and gamma rays.
Those gamma-ray bursts lasting lower than two seconds (about 30 %) are deemed quick bursts, normally emitting from areas with little or no star formation. Astronomers suppose these gamma-ray bursts consequence from mergers between two neutron stars or a neutron star merging with a black gap, comprising a “kilonova.”
The gamma-ray burst detected by NASA’s Neil Gehrels Swift Observatory again in 2019 fell into the lengthy class. But astronomers have been puzzled as a result of they discovered no proof of a corresponding supernova. “For every hundred events that fit into the traditional classification scheme of gamma-ray bursts, there is at least one oddball that throws us for a loop,” mentioned co-author Wen-fai Fong, an astrophysicist at Northwestern University. “However, it’s these oddballs that inform us essentially the most in regards to the spectacular range of explosions that the universe is able to.”
Intrigued, Fong and his co-authors adopted the burst’s fading afterglow utilizing the International Gemini Observatory, augmented with information collected by the Nordic Optical Telescopes and the Hubble Space Telescope. The afterglow enabled them to nail down the GRB’s location to a area simply 100 light-years away from the nucleus of an historical galaxy—i.e., very close to the supermassive black gap at its middle. They concluded that the burst had originated with the collision of two stars or stellar remnants.
That’s important as a result of there are three well-known processes for a star to die, relying on its mass. Massive stars explode in a supernova, whereas a star with the mass of our personal Sun will discard its outer layers and finally fade to grow to be a white dwarf. And the stellar remnants created from supernovae—neutron stars or black holes—can kind binary techniques and finally collide.
Now now we have a fourth various: stars in densely packed areas of historical galaxies can collide—an prevalence that may be very uncommon in lively galaxies, which are not as dense. An historical galaxy might have 1,000,000 stars packed into an space just some light-years throughout. And in this case, the gravitational results of being so close to a supermassive black gap would have altered the motions of these stars in order that they moved in random instructions. A collision can be sure to occur finally.
In reality, the authors counsel that these sorts of collisions may not even be that uncommon; we simply do not detect the telltale GRBs and afterglows due to all of the mud and fuel obscuring our view of the facilities of historical galaxies. If astronomers might choose up a gravitational wave signature in conjunction with such a GRB in the long run, that might inform them extra about this type of stellar demise.
“These new results show that stars can meet their demise in some of the densest regions of the Universe where they can be driven to collide,” mentioned co-author Andrew Levan, an astronomer with Radboud University in The Netherlands. “This is exciting for understanding how stars die and for answering other questions, such as what unexpected sources might create gravitational waves that we could detect on Earth.”
DOI: Nature Astronomy, 2023. 10.1038/s41550-023-01998-8 (About DOIs).