How huge, galactic black holes become brightest objects in universe
An illustration shows the IXPE spacecraft observing a blazar, a black hole surrounded by a disk of gas and dust with a bright jet of high-energy particles pointed toward Earth. (Reuters Photo)


Some black holes unleash huge and blazingly bright jets of high-energy particles into space – yes, black holes, the epitome of darkness, cause some of the brightest lights in space. Specifically, some humongous black holes that most galaxies are built around. While many of these galactic black holes are comparatively docile, like the one at our Milky Way's center, some are fierce – guzzling surrounding material and unleashing huge and blazingly bright jets.

Using data from the recently deployed Imaging X-ray Polarimetry Explorer (IXPE) orbiting observatory, researchers offered an explanation for how these jets become so luminous: subatomic particles called electrons becoming energized by shock waves moving at supersonic speed away from the black hole.

The researchers studied an exotic object called a blazar at the center of a large elliptical galaxy named Markarian 501 located about 460 million light years away from Earth in the direction of the constellation Hercules. A light year is the distance light travels in a year, 9.5 trillion kilometers (5.9 trillion miles).

Blazars are a subset of objects called quasars that are powered by supermassive black holes feeding on gas and other material at the center of galaxies and sending two jets of particles in opposite directions into space. Blazars are oriented such that one of their two jets from our vantage point on Earth is heading directly at us.

"Blazars are the most persistently bright objects in the observable universe. They are the most energetic. They have the biggest, scariest black holes. Everything that happens around them is so fascinating," said astronomer Yannis Liodakis of the Finnish Centre for Astronomy with ESO, lead author of the research published in the journal Nature.

Scientists have long sought to understand how the jets launched from blazars become so luminous and the behavior of the particles in them. The jets from this blazar extend to a distance of about a million light years.

IXPE, launched last December as a collaboration between the U.S. space agency NASA and the Italian Space Agency, measures the brightness and polarization – a property of light involving the orientation of the electromagnetic waves – of X-ray light from cosmic sources. Different phenomena, like shock waves or turbulence, present polarization "signatures."

The researchers found evidence that particles in the jet become energized when hit with a shock wave propagating outward inside the stream and emit X-rays as they accelerate. A shock wave is produced when something moves faster than the speed of sound through a medium like air – as a supersonic jet does as it flies through Earth's atmosphere – or a region with particles and magnetic fields called plasma, as in this case.

"The light that we see from the jets comes from electrons," said Boston University astrophysicist and study co-author Alan Marscher. "X-rays of the type that we observe in Markarian 501 can only come from extremely high-energy electrons."

The driving force behind this drama is a black hole, an extraordinarily dense object with gravity so powerful that not even light can escape. The supermassive black hole at the center of Markarian 501 has a mass somewhere around a billion times the mass of our sun. That is about 200 times larger than the mass of Sagittarius A*, the Milky Way's supermassive black hole.

"Black holes are unique laboratories to study fundamental physics in extreme conditions we cannot replicate on Earth," Liodakis said.

"However, before we can use them as such, we need to understand all the physical processes that take place. For many years we would observe high-energy light from those sources and had a few theories on how the particles that emit that light would be energized. The X-ray polarization capabilities of IXPE allowed us for the first time to directly test our theories," Liodakis said.