Scientists had already identified 67 growing black holes within this image, obscured by "cocoons" or surrounding envelopes of dust and gas. Now, with this new study, researchers have identified these 28 supermassive black holes, which were previously miscategorized as either slowly growing black holes with low-densities or without cocoons or distant galaxies, according to a statement.
"This could be considered a case of mistaken black hole identity," co-author Marco Chiaberge of Space Telescope Science Institute in Baltimore, Maryland, said in the statement. "But these black holes are exceptionally good at hiding exactly what they are."
With these new observations, these objects were found to actually be supermassive black holes, the largest type of black hole, which grow by pulling in surrounding material with their intense gravitational pull. Material sucked in by the black hole heats up and emits radiation in a wide variety of wavelengths, including X-rays - hence why X-ray telescopes are so helpful in observing these far-off objects.
To come to this conclusion, Lambridges and her team compared their data with what is expected for a growing black hole and predicted the amount of X-rays they should expect from each object. They found a much lower level of X-rays than they anticipated from these 28 X-ray sources. This led them to find that the cocoon of gas and dust surrounding the objects is about 10 times denser than previously estimated.
Taking this higher-density cocoon into account, the team was able to show how these black holes produce more X-rays than previously thought, as the cocoon stops a large amount of X-rays from escaping and being observed from Earth. As these cocoons feed growing black holes, finding that these cocoons are much denser than expected led the researchers to find that the black holes are growing quickly as they are fueled by these surrounding envelopes.
This research is important because it supports theoretical models that estimate how many black holes are out in the universe, how fast they may be growing and what (like a cocoon of gas and dust) might be obscuring them and altering how they are seen out in the cosmos.
This work was described in a study published July 15 in The Astrophysical Journal.
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