Astronomers have observed jellyfish galaxies ‘feeding’ supermassive black holes for the first time.
The discovery is a key clue in the long-standing puzzle to understand how galaxies form and change in our expanding and evolving universe.
As their nickname suggests, jellyfish galaxies appear to have tentacles, which are actually streams of gas and stars that extend out from the galaxy body. The tentacles form because the gas within the galaxy is peeled off by a force called “ram pressure stripping.”
This happens when a galaxy moves into the hot gas of a galaxy cluster, falling into it at high velocity. The dense gas that fills the cluster acts like a strong wind on the galaxy gas and it strips it away to create the tails.
This new research shows that ram pressure funnels the gas towards the galaxy center, feeding the black hole, revealing a previously unknown mechanism by which the black holes can be fed.
“Supermassive black holes are present in almost all galaxies, so why are only a few accreting matter and shining brightly?”
Benedetta Vulcani says that jellyfish galaxies are key to understanding the evolution of our universe, as they are galaxies caught in the middle of a dramatic transformation.
“It is now well established that most, if not all, galaxies host at their center a supermassive black hole of a few million to a few billion solar masses,” says Vulcani, an astronomer from the University of Melbourne.
“We want to understand why only a small fraction of supermassive black holes are active. Supermassive black holes are present in almost all galaxies, so why are only a few accreting matter and shining brightly?”
And it appears that cosmic jellyfish are the answer. But they are rare—to date. Just over 400 candidate jellyfish galaxies have been found.
Vulcani explains that jellyfish galaxy tentacles extend for tens of thousands of light-years beyond their galactic discs. “The process is named ‘ram’ because it is very powerful,” she says.
In the stripped gas, new stars are formed. Hence, the tails are visible also in the optical light, emitted by the stars.
For this research, the team identified the galaxies with the longest or more extended “tentacles.” They found that six out of the seven jellyfish galaxies were found to host a supermassive black hole at the center, feeding on the surrounding gas.
Black holes kill more stars than astronomers expected
Team leader Bianca Poggianti from the INAF-Astronomical Observatory of Padova says this fraction is unexpectedly high—among galaxies in general the fraction is less than one in ten.
“This strong link between ram pressure stripping and active black holes was not predicted and has never been reported before,” she says.
It seems that the central black hole is being fed because some of the gas, rather than being removed, reaches the galaxy center.
“This is a field of research where we might expect other surprises, and it is pretty much uncharted territory…”
These findings suggest a novel mechanism for gas to be funneled towards the black hole’s neighborhood. This result is important because it provides a new piece in the puzzle of the poorly understood connections between supermassive black holes and their host galaxies.
Poggianti adds that the current observations are part of a much more extensive study of many more jellyfish galaxies mostly in clusters, but also includes some in groups and isolated, that is currently in progress.
“This survey, when completed, will reveal how many, and which, gas-rich galaxies entering clusters go through a period of increased activity at their cores,” says Poggianti.
“Most importantly, it will shed light on whether ram pressure stripping can be effective also in groups and to observe what other processes can be at work in less crowded regions of the Universe to remove gas from galaxies.”
No one has ever seen 2 black holes this close together
The team used the MUSE (Multi-Unit Spectroscopic Explorer) instrument on the Very Large Telescope (VLT) at the European Southern Obervatory’s Paranal facility in Chile to study how gas can be stripped from galaxies in optical light. Observations with different instruments at different wavelengths allow astronomers to look at the galaxies in different ways, creating a more complete picture of how the gas is moving.
“This is a field of research where we might expect other surprises, and it is pretty much uncharted territory,” says Vulcani.
The findings appear in the journal Nature.
Source: University of Melbourne