The jet was produced by a quasar named GB 1428+4217 (GB 1428). Giant black holes at the centers of galaxies can pull in matter at a rapid rate, producing the quasar phenomenon. The energy released as particles fall toward the black hole generates intense radiation and powerful beams of high-energy particles that blast away from the black hole at nearly the speed of light. These particle beams can interact with magnetic fields or ambient photons to produce jets of radiation.
“We’re excited about this result not just because it’s a record holder, but because very few X-ray jets are known in the early universe,” said Teddy Cheung of the National Academy of Sciences in Washington, D.C.
As the electrons in the jet fly away from the quasar, they move through a sea of background photons left behind after the Big Bang. When a fast-moving electron collides with one of these so-called cosmic microwave background photons, it can boost the photon’s energy into the X-ray band.
“Since the brightness of the jet in X-rays depends, among other things, on how fast the electrons are moving away from the black hole, discoveries like the jet in GB 1428 tell us something about the environment around supermassive black holes and their host galaxies not that long after the Big Bang,” said Lukasz Stawarz from the Japan Aerospace Exploration Agency in Kanagawa.
Because the quasar is seen when the universe is at an age of about 1.3 billion years, less than 10 percent of its current value, the cosmic background radiation is a thousand times more intense than it is now. This makes the jet much brighter and compensates, in part, for the dimming due to distance.
“We’re lucky that the universe gives us this natural amplifier and lets us detect this object with relatively short exposures,” said Aneta Siemiginowska of the Harvard-Smithsonian Center for Astrophysics in Cambridge, Massachusetts. “Otherwise we might miss important physical processes happening at very large distances from Earth and as far away as GB 1428.”
While there is another possible source of X-rays for the jet — radiation from electrons spiraling around magnetic field lines in the jet — the scientists favor the idea that the cosmic background radiation is being boosted because the jet is so bright.
Prior to the discovery of the jet in GB 1428, the most distant X-ray jet known was 12.2 billion light-years away, and another is located at about 12 billion light-years. A very similar shaped jet in GB 1428 was also detected in radio waves with the National Science Foundation’s Very Large Array (VLA).
The particle beams that produce these three extremely distant X-ray jets appear to be moving slightly more slowly than jets from galaxies that are not as far away. This may be because the jets were less energetic when launched from the black hole or because they are slowed down more by their environment.
The researchers think the length of the jet in GB 1428 is at least 230,000 light-years, or about twice the diameter of the entire Milky Way Galaxy. This jet is only seen on one side of the quasar in the Chandra and VLA data. When combined with previously obtained evidence, this suggests that the jet is pointed almost directly toward us. This configuration would boost the X-ray and radio signals for the observed jet and diminish those for a jet presumably pointed in the opposite direction.
Observations were also taken of GB 1428 with a set of radio telescopes at different locations around Earth that allows details to be resolved on exceptionally small scales. They revealed the presence of a much smaller jet, about 1,900 light-years long, that points in a similar direction to the X-ray jet.
The jet was produced by a quasar named GB 1428+4217 (GB 1428). Giant black holes at the centers of galaxies can pull in matter at a rapid rate, producing the quasar phenomenon. The energy released as particles fall toward the black hole generates intense radiation and powerful beams of high-energy particles that blast away from the black hole at nearly the speed of light. These particle beams can interact with magnetic fields or ambient photons to produce jets of radiation.
“We’re excited about this result not just because it’s a record holder, but because very few X-ray jets are known in the early universe,” said Teddy Cheung of the National Academy of Sciences in Washington, D.C.
As the electrons in the jet fly away from the quasar, they move through a sea of background photons left behind after the Big Bang. When a fast-moving electron collides with one of these so-called cosmic microwave background photons, it can boost the photon’s energy into the X-ray band.
“Since the brightness of the jet in X-rays depends, among other things, on how fast the electrons are moving away from the black hole, discoveries like the jet in GB 1428 tell us something about the environment around supermassive black holes and their host galaxies not that long after the Big Bang,” said Lukasz Stawarz from the Japan Aerospace Exploration Agency in Kanagawa.
Because the quasar is seen when the universe is at an age of about 1.3 billion years, less than 10 percent of its current value, the cosmic background radiation is a thousand times more intense than it is now. This makes the jet much brighter and compensates, in part, for the dimming due to distance.
“We’re lucky that the universe gives us this natural amplifier and lets us detect this object with relatively short exposures,” said Aneta Siemiginowska of the Harvard-Smithsonian Center for Astrophysics in Cambridge, Massachusetts. “Otherwise we might miss important physical processes happening at very large distances from Earth and as far away as GB 1428.”
While there is another possible source of X-rays for the jet — radiation from electrons spiraling around magnetic field lines in the jet — the scientists favor the idea that the cosmic background radiation is being boosted because the jet is so bright.
Prior to the discovery of the jet in GB 1428, the most distant X-ray jet known was 12.2 billion light-years away, and another is located at about 12 billion light-years. A very similar shaped jet in GB 1428 was also detected in radio waves with the National Science Foundation’s Very Large Array (VLA).
The particle beams that produce these three extremely distant X-ray jets appear to be moving slightly more slowly than jets from galaxies that are not as far away. This may be because the jets were less energetic when launched from the black hole or because they are slowed down more by their environment.
The researchers think the length of the jet in GB 1428 is at least 230,000 light-years, or about twice the diameter of the entire Milky Way Galaxy. This jet is only seen on one side of the quasar in the Chandra and VLA data. When combined with previously obtained evidence, this suggests that the jet is pointed almost directly toward us. This configuration would boost the X-ray and radio signals for the observed jet and diminish those for a jet presumably pointed in the opposite direction.
Observations were also taken of GB 1428 with a set of radio telescopes at different locations around Earth that allows details to be resolved on exceptionally small scales. They revealed the presence of a much smaller jet, about 1,900 light-years long, that points in a similar direction to the X-ray jet.
