Glow from the Big Bang allows discovery of distant black hole jet

Chandra X-ray Center / NASA's Marshall Space Flight Center Press Release

A jet from a supermassive black hole some 11 billion light-years away in the northern constellation of Lynx has been found using the Chandra X-ray Observatory. Known as B3 0727+409, the black hole has an X-ray jet 16 million light-years across. The light from this jet was emitted just 2.7 billion years after the Big Bang when the universe was only one fifth its current age. This composite image uses X-rays from NASA's Chandra X-ray Observatory with optical data from Digitised Sky Survey. Image credits: X-ray: NASA/CXC/ISAS/A.Simionescu et al, Optical: DSS.
A jet from a supermassive black hole some 11 billion light-years away in the northern constellation of Lynx has been found using the Chandra X-ray Observatory. Known as B3 0727+409, the black hole has an X-ray jet 16 million light-years across. The light from this jet was emitted just 2.7 billion years after the Big Bang when the universe was only one fifth its current age. This composite image uses X-rays from NASA’s Chandra X-ray Observatory with optical data from Digitised Sky Survey. Image credits: X-ray: NASA/CXC/ISAS/A.Simionescu et al, Optical: DSS.

Astronomers have used NASA’s Chandra X-ray Observatory to discover a jet from a very distant supermassive black hole being illuminated by the oldest light in the universe. This discovery shows that black holes with powerful jets may be more common than previously thought in the first few billion years after the Big Bang.

The light detected from this jet was emitted when the universe was only 2.7 billion years old, a fifth of its present age. At this point, the intensity of the cosmic microwave background radiation, or CMB, left over from the Big Bang was much greater than it is today.

The length of the jet, found in the system known as B3 0727+409, is at least 300,000 light years. Many long jets emitted by supermassive black holes have been detected in the nearby universe, but exactly how these jets give off X-rays has remained a matter of debate. In B3 0727+409, it appears that the CMB is being boosted to X-ray wavelengths.

“Because we’re seeing this jet when the universe was less than three billion years old, the jet is about 150 times brighter in X-rays than it would be in the nearby universe,” said Aurora Simionescu at JAXA’s Institute of Space and Astronautical Studies (ISAS) who led the study.

As the electrons in the jet fly from the black hole at close to the speed of light, they move through the sea of CMB radiation and collide with microwave photons, boosting the energy of the photons up into the X-ray band to be detected by Chandra. This implies that the electrons in the B3 0727+409 jet must keep moving at nearly the speed of light for hundreds of thousands of light-years.

Electrons in black hole jets usually emit strongly at radio wavelengths, so typically these systems are found using radio observations. The discovery of the jet in B3 0727+409 is special because so far almost no radio signal has been detected from this object, while it is easily seen in the X-ray image.

“We essentially stumbled onto this remarkable jet because it happened to be in Chandra’s field of view while we were observing something else,” explains co-author Lukasz Stawarz of Jagiellonian University in Poland.

Scientists have so far identified very few jets distant enough that their X-ray brightness is amplified by the CMB as clearly as in the B3 0727+409 system. But, Stawarz adds, “if bright X-ray jets can exist with very faint or undetected radio counterparts, it means that there could be many more of them out there because we haven’t been systematically looking for them.”

“Supermassive black hole activity, including the launching of jets, may be different in the early universe than what we see later on,” said co-author Teddy Cheung of the Naval Research Laboratory in Washington DC. “By finding and studying more of these distant jets, we can start to grasp how the properties of supermassive black holes might change over billions of years.”

These results were published recently in The Astrophysical Journal Letters and appear online.