The galaxy, called NGC2110, is in the constellation of Orion.
Using the giant Keck telescopes in Hawaii, the researchers, Professor Jeremy Mould and PhD student Mark Durré from Swinburne’s Centre for Astrophysics and Supercomputing, found four star clusters, very close (in astronomical terms) to a black hole.
“These star clusters hadn’t been seen before because they are hidden by dust clouds around the black hole and because they appear very tiny, but they can be observed in infrared radiation that penetrates the clouds,” Mr Durré said.
“The Keck telescope also uses ‘adaptive optics’, which removes the atmospheric shimmer that blurs images.”
Supermassive black holes – condensations of matter so dense that not even light can escape from its gravity – are thought to be at the centre of all large galaxies.
“Our own galaxy, the Milky Way, has a black hole that is almost four million times the mass of our Sun,” Mr Durré said. “NGC2110 has a black hole about 100 times bigger.”
The black hole produces huge amounts of energy that comes from gas and dust falling into it. As the material streams in, it hits an accretion disk – a spinning ring of superheated gas around the black hole’s equator. Enormous quantities of radiation shine out and some of the matter also gets spewed out in jets, which are most clearly observed by radio telescopes.
Tides from the black hole and other features of the galaxy can help form star clusters – collections of thousands of stars which are all formed together from a gas and dust cloud. In turn, gas out-streaming from the young stars in the clusters can feed and energise the black hole.
“The jets can compress gas around them to start this star cluster formation, but they can also stop the process by blowing the gas completely out of the galaxy. The fine details of how the matter is funnelled in and how the black hole affects the galaxy around it remain fascinating questions for astronomers as they try to work out how galaxies form.”
Mr Durré said that according to computer simulations, star clusters should form like beads or pearls on a string in a ring around the black hole – and this is just what the researchers have observed.
“After many millions of years, these clusters will be torn apart, again by tidal forces, and gradually settle into a central collection closer around the black hole.” Mr Durré said.
This research has been published in the Astrophysical Journal.