The finding, published October 11 in The Astrophysical Journal, shows that winds of energetic gas and particles blasted out by supermassive black holes can stop star formation in dwarf galaxies. It is the first time that black hole winds in dwarf galaxies have been studied in such detail, according to the team. And it’s an intriguing find, because astronomers didn’t expect such strong winds from the black holes in dwarf galaxies. They also didn’t expect those winds to stop, or quench, star formation galaxy-wide.
Stopping star formation
When they are young, galaxies have a lot of available gas to form stars, which are birthed when the gas cools, contracts, and ultimately collapses into stars. But winds can stop star formation by either heating up the gas so it can’t cool and collapse, or by simply pushing the gas out of the galaxy entirely, removing the raw materials from which stars are born.
In larger galaxies, outflows from supermassive black holes have been linked to the shutdown of star formation. But not in dwarf galaxies. “Typically, winds driven by stellar processes [such as supernovae] are common in dwarf galaxies and constitute the dominant process for regulating the amount of gas available in dwarf galaxies for forming stars,” said first author Christina M. Manzano-King at the University of California, Riverside, in a press release.
But the team spotted winds in six dwarf galaxies that clearly came from the galaxies’ actively feeding black holes. Those winds were surprisingly swift and strong, and negatively impacted the galaxies’ ability to form new stars, said study co-author Laura V. Sales, also at Riverside. The winds are so strong that they push the gas out beyond the galaxy’s boundaries, making it unavailable to form stars.
How to build a big galaxy
The finding has implications for our understanding of how galaxies form and grow. Over time, smaller galaxies combine to create bigger ones. So, dwarf galaxies still around today represent the building blocks of larger galaxies, giving astronomers a peek into their past. These dwarf galaxies are thus a crucial component of understanding how bigger galaxies assemble, and anything that affects their behavior, in turn, is important.
That “anything” now includes, it seems, their supermassive black holes. So, this finding is an important step toward building a better understanding of both dwarf galaxies and the larger galaxies they become a part of.
“Theoretical models for the formation and evolution of galaxies have not included the impact of black holes in dwarf galaxies,” Sales said. “Our findings show that galaxy formation models must include black holes as important, if not dominant, regulators of star formation in dwarf galaxies.”