Hubble reveals galaxy gas flow and star birth regulated by black-hole jets

The Space Telescope Science Institute Press Release

This artist's rendering shows a central black hole interacting with gas in the galaxy's halo to create a self-regulating cycle. In this cycle, jets shooting out of the galaxy's centre heat a halo of surrounding gas, controlling the rate at which the gas cools and falls into the galaxy to form stars. Image credit: NASA, ESA, and P. Jeffries (STScI).
This artist’s rendering shows a central black hole interacting with gas in the galaxy’s halo to create a self-regulating cycle. In this cycle, high-energy jets shooting out of the galaxy’s centre heat a halo of surrounding gas, controlling the rate at which the gas cools and falls into the galaxy to form stars. Image credit: NASA, ESA, and P. Jeffries (STScI).
Combining Hubble data with observations from a suite of ground-based and space telescopes, two independent teams found that the black hole, jets, and newborn stars are all parts of a self-regulating cycle.

“Think of the gas surrounding a galaxy as an atmosphere,” explained the lead of the first study, Megan Donahue of Michigan State University. “That atmosphere can contain material in different states, just like our own atmosphere has gas, clouds, and rain. What we are seeing is a process like a thunderstorm. As the jets propel gas outward from the center of the galaxy, some of that gas cools and precipitates into cold clumps that fall back toward the galaxy’s center like raindrops.”

“The ‘raindrops’ eventually cool enough to become star-forming clouds of cold molecular gas, and the far-ultraviolet capabilities of Hubble allowed us to directly observe these ‘showers’ of star formation,” explained the lead of the second study, Grant Tremblay of Yale University. “We know that these showers are linked to the jets because they’re found in filaments and tendrils that wrap around the jets or hug the edges of giant bubbles that the jets have inflated,” said Tremblay. “And they end up making a swirling ‘puddle’ of star-forming gas around the central black hole.”

This sample of galaxies, as seen by Hubble, shows chains of star formation in ultraviolet light. This star formation in each galaxy is a product of the action of the jets from a central black hole that controls infalling gas from the galaxy's halo. Image credit: NASA, ESA, G. Tremblay (Yale University), and R. Mittal (Rochester Institute of Technology, and Max Planck Institute for Gravitational Physics).
This sample of galaxies, as seen by Hubble, shows chains of star formation in ultraviolet light. This star formation in each galaxy is a product of the action of the jets from a central black hole that controls infalling gas from the galaxy’s halo. Image credit: NASA, ESA, G. Tremblay (Yale University), and R. Mittal (Rochester Institute of Technology, and Max Planck Institute for Gravitational Physics).
But what should be a monsoon of raining gas is reduced to a mere drizzle by the black hole. While some outwardly flowing gas will cool, the black hole heats the rest of the gas around a galaxy, which prevents the whole gaseous envelope from cooling more quickly. The entire cycle is a self-regulating feedback mechanism, like the thermostat on a house’s heating and cooling system, because the “puddle” of gas around the black hole provides the fuel that powers the jets. If too much cooling happens, the jets become more powerful and add more heat. And if the jets add too much heat, they reduce their fuel supply and eventually weaken.

This discovery explains the mystery of why many elliptical galaxies in the present-day universe are not ablaze with a higher rate of star birth. For many years, the question has persisted of why galaxies awash in gas don’t turn all of that gas into stars. Theoretical models of galaxy evolution predict that present-day galaxies more massive than the Milky Way should be bursting with star formation, but that is not the case.

Now scientists understand this case of arrested development, where a cycle of heating and cooling keeps star birth in check. A light drizzle of cooling gas provides enough fuel for the central black hole’s jets to keep the rest of the galaxy’s gas hot. The researchers show that galaxies don’t need fantastic and catastrophic events such as galaxy collisions to explain the showers of star birth they see.

The study led by Donahue looked at far-ultraviolet light from a variety of massive elliptical galaxies found in the Cluster Lensing And Supernova Survey with Hubble (CLASH), which contains elliptical galaxies in the distant universe. These included galaxies that are raining and forming stars, and others that are not. By comparison, the study by Tremblay and his colleagues looked at only elliptical galaxies in the nearby universe with fireworks at their centres. In both cases, the filaments and knots of star-birth appear to be very similar phenomena. An earlier, independent study, led by Rupal Mittal of the Rochester Institute of Technology and the Max Planck Institute for Gravitational Physics, also analysed the star birth rates in the same galaxies as Tremblay’s sample.

In this comparison of actual observations with simulations, the top images show Hubble observations of the density of gas in the central portion of two galaxies. The bottom images are computer simulations that are remarkably similar to the Hubble observations. Knots of star formation in the two galaxies show how gas falling into a galaxy's centre is controlled by jets from the central black hole. Image credit: NASA, ESA, M. Donahue (Michigan State University), and Y. Li (University of Michigan).
In this comparison of actual observations with simulations, the top images show Hubble observations of the density of gas in the central portion of two galaxies. The bottom images are computer simulations that are remarkably similar to the Hubble observations. Knots of star formation in the two galaxies show how gas falling into a galaxy’s centre is controlled by jets from the central black hole. Image credit: NASA, ESA, M. Donahue (Michigan State University), and Y. Li (University of Michigan).
The researchers were aided by an exciting, new set of computer simulations of the hydrodynamics of the gas flows developed by Yuan Li of the University of Michigan. “This is the first time we now have models in hand that predict how these things ought to look,” explained Donahue. “And when we compare the models to the data, there’s a stunning similarity between the star-forming showers we observe and ones that occur in simulations. We’re getting a physical insight that we can then apply to models.”

Along with Hubble, which shows where the old and the new stars are, the researchers used the Galaxy Evolution Explorer (GALEX), the Herschel Space Observatory, the Spitzer Space Telescope, the Chandra X-ray Observatory, the X-ray Multi-Mirror Mission (XMM-Newton), the National Radio Astronomy Observatory (NRAO)’s Jansky Very Large Array (JVLA), the National Optical Astronomy Observatory (NOAO)’s Kitt Peak WIYN 3.5-metre telescope, and the Magellan Baade 6.5-metre telescope. Together these observatories paint the complete picture of where all of the gas is, from the hottest to the coldest. The suite of telescopes shows how galaxy ecosystems work, including the black hole and its influence on its host galaxy and the gas surrounding that galaxy.