These astronomical bodies, with masses ranging from 100 to a few thousand solar masses, are considered the missing link in the evolution of supermassive entities. Their elusive nature makes them challenging to pinpoint, though it's speculated they are more prevalent than believed. Candidates for these intermediate-mass black holes have been detected by the James Webb and Hubble telescopes, with confirmation pending.
To investigate the vicinity of Sagittarius A*, the study's authors, including a Nobel laureate recognized for proving the existence of this black hole, utilized the orbit of the star named S2. Orbiting closely to the supermassive entity, S2's trajectory could indicate the presence of another sizable mass. In essence, another black hole near Sagittarius A* would disrupt S2's orbit, particularly if it's an intermediate hole, and even more so if supermassive. The star completes an orbit around Sagittarius A* every 16 years, with over two decades of observational data available. Despite no detected gravitational disruptions in S2's orbit, the researchers hypothesize the intermediate black hole may still be in proximity. They suggest that if the supposed intermediate black hole orbits Sagittarius A* beyond S2's orbit, its mass would range between 1,000 and 10,000 suns. If it's closer to Sagittarius A* than the star, it would be as large as 400 solar masses at maximum.
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