Scientists watched as a three-quasar system merged in a supercomputer simulation of the universe to birth a black hole 300 billion times as massive as the sun.
Glimpsed only occasionally at the hearts of massive clusters of galaxies, ultramassive black holes are some of the largest and most elusive objects in the universe. These black hole behemoths have masses exceeding that of 10 billion suns, making them far more monstrous than even the supermassive black holes found at the centers of galaxies like the Milky Way, and their tremendous size has long perplexed astronomers.
Now, researchers studying a rare galaxy merger with three supermassive black holes at its center may have finally discovered the origins of these cosmic monsters.
This Hubble Space Telescope image captures the rare sight of three merging galaxies, each containing a supermassive black hole. According to recent supercomputer simulations, triple mergers such as this may be how ultramassive black holes — those tens of billions of times the mass of the Sun — formed so quickly in the early universe.
Using a high-resolution cosmological simulation called ASTRID, the team modeled the evolution of the universe as it appeared about 11 billion years ago. In the simulation, the team witnessed the birth of an ultramassive black hole following the merger of the three galaxies. Each of these galaxies contained its own quasar, a supermassive black hole that feeds on gas and powers massive outbursts of radiation that can outshine all the stars in their host galaxies combined.
When the triple quasars met, they formed an even more massive black hole while simultaneously triggering a feeding frenzy that allowed the combined object to reach ultramassive status.
“We found a very rare system containing a quasar triplet at the epoch of the cosmic noon — about 11 billion years ago when galaxies and supermassive black holes reach their peak activity,” lead study author Yueying Ni(opens in new tab), a postdoctoral fellow at the Harvard-Smithsonian Center for Astrophysics, told Live Science via email. “The system is composed of three bright quasars powered by supermassive black holes, each residing in massive galaxies about 10 times the mass of our galaxy, the Milky Way.”
Astrid simulations run on the Texas Advanced Computing Center’s Frontera supercomputer reveal how ultramassive black holes may have formed in such a short amount of time after the Big Bang. Shown here is a triple quasar system centered on the most massive black hole-driven quasar (BH1). The red and yellow lines show the trajectories the two other massive quasars (BH2 and BH3) took as they spiraled into each other and merged.
Supercomputer simulations show three galaxies with supermassive black holes at their centers merging into one galaxy with an ‘ultramassive’ black hole at its heart.
Supercomputer simulations show three galaxies with supermassive black holes at their centers merging into one galaxy with an ‘ultramassive’ black hole at its heart. (Image credit: Ni et al./ Astrophysical Journal Letters)
The team’s simulation showed the triple quasars likely merged over the course of 150 million years and formed the most massive black hole in the entire simulation, with a mass greater than 300 billion times that of the sun — or more than every star in the Milky Way combined, according to Ni.
“This indicates a possible formation channel of these ultramassive black holes by extreme merger events of multiple supermassive black holes,” Ni said.
The rarity of triple-quasar systems may explain why ultramassive black holes in the actual universe are so elusive.
“Although in general, we expect more massive systems to host more massive black holes, ultramassive black holes are elusive, because black hole growth is a quite self-regulated process,” Ni explained. “In an isolated system/galaxy, when a black hole grows massive enough, it will deposit strong feedback to its surroundings and limit itself from further rapid growth.”
In other words, astronomers expect that the formation of an ultramassive black hole with a mass even at the lower end of the spectrum (about 10 billion times that of the sun) would happen only in very rare and extreme scenarios. In this case, that comes in the form of repeated mergers of three very massive galaxies.
As follow-up work, the team intends to do a statistical analysis of multiple-quasar systems in the ASTRID simulation to study the properties of their host galaxies, make mock observations, and trace how the ultramassive black hole and the host galaxy evolve as the simulation proceeds.
Source: livescience.com
