Astronomers have discovered several bizarre objects at the Galactic Center near the Milky Way’s supermassive black hole that are concealing their true identity behind a smokescreen of dust; they look like gas clouds, but behave like stars.
At the American Astronomical Society Meeting in Denver, a team of researchers, led by UCLA Postdoctoral Scholar Anna Ciurlo, announced the results they obtained using 12 years of data taken from the W. M. Keck Observatory on Maunakea, Hawaii, saying:
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“These compact dusty stellar objects move extremely fast and close to our Galaxy’s supermassive black hole. It is fascinating to watch them move from year to year.
“How did they get there? And what will they become? They must have an interesting story to tell.”
The researchers made their discovery by obtaining spectroscopic measurements of the Galactic Center’s gas dynamics using Keck Observatory’s OH-Suppressing Infrared Imaging Spectrograph (OSIRIS). Randy Campbell, science operations lead at Keck Observatory, said:
“We started this project thinking that if we looked carefully at the complicated structure of gas and dust near the supermassive black hole, we might detect some subtle changes to the shape and velocity.
“It was quite surprising to detect several objects that have very distinct movement and characteristics that place them in the G-object class, or dusty stellar objects.”
Astronomers first discovered G-objects at the Milky Way’s supermassive black hole more than a decade ago; G1 was first seen in 2004, and G2 was discovered in 2012. Both were thought to be gas clouds until they made their closest approach to the supermassive black hole. G1 and G2 somehow managed to survive the supermassive black hole’s gravitational pull, which can shred gas clouds apart.
UCLA Astronomy Professor Mark Morris, a co-principal investigator and fellow member of UCLA’s Galactic Center Orbits Initiative (GCOI), said:
“If they were gas clouds, G1 and G2 would not have been able to stay intact.
“Our view of the G-objects is that they are bloated stars — stars that have become so large that the tidal forces exerted by the central black hole can pull matter off of their stellar atmospheres when the stars get close enough, but have a stellar core with enough mass to remain intact. The question is then, why are they so large?”
It appears that a lot of energy was dumped into the G-objects, causing them to swell up and grow larger than typical stars. GCOI thinks that these G-objects are the result of stellar mergers — where two stars orbiting each other, known as binaries, crash into each other due to the gravitational influence of the giant black hole.
Supermassive black holes cause nearby binary stars to collide
Over a long period of time, the black hole’s gravity alters the binary stars’ orbits until the duo collides. The combined object that results from this violent merger could explain where the excess energy came from. Morris said:
“In the aftermath of such a merger, the resulting single object would be “puffed up,” or distended, for a rather long period of time, perhaps a million years, before it settles down and appears like a normal-sized star.”
Andrea Ghez, founder and director of GCOI, said:
“This is what I find most exciting.
“If these objects are indeed binary star systems that have been driven to merge through their interaction with the central supermassive black hole, this may provide us with insight into a process which may be responsible for the recently discovered stellar mass black hole mergers that have been detected through gravitational waves.”
What makes G-objects unusual is their “puffiness.” It is rare for a star to be cloaked by a layer of dust and gas so thick that astronomers do not see the star directly. They only see the glowing envelope of dust. To see the objects through their hazy environment, Campbell explained how he developed a tool called OSIRIS-Volume Display (OsrsVol):
“OsrsVol allowed us to isolate these G-objects from the background emission and analyze the spectral data in three dimensions: two spatial dimensions, and the wavelength dimension that provides velocity information.
“Once we were able to distinguish the objects in a 3-D data cube, we could then track their motion over time relative to the black hole.”
Ciurlo added:
“Keck Observatory has been observing the Galactic Center every year for 20 years with some of the best instruments and technologies.
“This alone gives a very high quality and consistent data set, which allowed us to go deep into the analysis of the data.”
These newly discovered infrared sources could potentially be G-objects — G3, G4, and G5 — because they share the physical characteristics of G1 and G2. The team will continue to follow the size and shape of the G-objects’ orbits, which could provide important clues as to how they formed.
Astronomers will especially be paying close attention when these dusty stellar compact objects make their closest approach to the supermassive black hole. This will allow them to further observe their behavior and see whether the objects remain intact just as G1 and G2 did, or become a snack for the supermassive black hole. Only then will they give away their true nature. Morris said:
“We’ll have to wait a few decades for this to happen; about 20 years for G3, and decades longer for G4 and G5.
“In the meantime, we can learn more about these puffballs by following their dynamical evolution using OSIRIS.”
Ciurlo added:
“Understanding G-objects can teach us a lot about the Galactic Center’s fascinating and still mysterious environment. There are so many things going on that every localized process can help explain how this extreme, exotic environment works.”
Provided by: W. M. Keck Observatory [Note: Materials may be edited for content and length.]
