Scientists think that Big Bird could have been produced by an ancient, super powerful galactic center called a «
blazar» from 9.5 billion light - years away.
When a jet faces Earth, that's
a blazar.
The researchers hope to test this hypothesis with larger
blazar samples.
«We typically see apparent speeds in
blazar jets that are about five times the speed of light, and that corresponds to a true speed of more than 98 percent of light speed,» Piner said.
VLBA sequence of
blazar 0827 +243 over about 8.4 months.
This sequence shows plasma moving away from
the blazar's core.
This hybrid
blazar idea implies that the luminosity of BL Lacs should decrease as their core black holes continue to lose energy and spin.
«We can think of one
blazar class as a gas - guzzling car and the other as an energy - efficient electric vehicle,» study lead researcher Marco Ajello, an astrophysicist at Clemson University in South Carolina, said in a statement.
Not all the high - energy gamma rays emitted by
a blazar, however, make it all the way across billions of light - years to Earth; some strike a hapless EBL photon along the way.
When a high - energy gamma ray from
a blazar strikes air molecules in the upper regions of Earth's atmosphere, it produces a cascade of charged subatomic particles.
The attached figure illustrates how energetic gamma rays (dashed lines) from a distant
blazar strike photons of extragalactic background light (wavy lines) and produce pairs of electrons and positrons.
Instead of streaming out of a metal casing and turbine,
a blazar's jets «are confined and focused by coiled magnetic fields originating near the [supermassive] black hole.»
Now, Readhead and his colleagues argue that they're seeing
the blazar's black hole emit tiny burps of plasma, magnified hundreds of times by a new kind of gravitational lens.
This behaviour and further findings from observations can be best explained with an interesting assumption: Although the brightness variations in the gamma ray region also originate from the flare ups in
the blazar, they are amplified to different degrees by the gravitational lens effect of individual stars in the foreground galaxy.
The detail on the right is a simulation of the micro-gravitational lens effect in the gamma ray region; direct observation of the orange ring — it also represents images of
the blazar — is not possible due to its small size.
Astronomers had already recorded intensity flare ups in the radio region which originated from events in
the blazar.
J1415 +1320 is what's known as
a blazar, a bright galaxy with a gluttonous supermassive black hole at its center (SN: 3/4/17, p. 13).
The light of
the blazar behind it passes through this space well and takes a detour — as if it were passing through a lens.
PKS 1830 - 211 thus appears in the sky as two images; and these images are brighter than
the blazar would be without this lens effect.
This is
a blazar — a rare case in which one of the two jets happens to be directed towards Earth so that the astronomers look directly into the jet along the longitudinal axis.
Looking at a distant galaxy: the radio chart (left) shows the image of
the blazar PKS 1830 - 211 distorted by the gravitational lens effect.
It so happens that there is a galaxy roughly half way between Earth and
the blazar, which is billions of light years away.
Partially dimmed x-rays (dips in graph) from a flaring
blazar (right) reveal two filaments of hot, diffuse matter in the vast spaces between galaxies.
Astronomer Fabrizio Nicastro of the Harvard - Smithsonian Center for Astrophysics in Cambridge, Massachusetts, and his colleagues monitored the galaxy Markarian 421, which contains a «
blazar» — an active black hole that aims powerful jets of energy toward Earth.
Related sites Abstract of paper, with link to full text Chandra X-ray Observatory FUSE satellite, used in similar studies of lower - temperature gas Observations of Markarian 421
blazar Shull's home page
The discovery, which was accomplished by comparing data from NASA's Wide - field Infrared Survey Explorer (WISE) and Fermi Gamma - ray Space Telescope, has enabled the researchers to uncover dozens of new
blazar candidates.
«NASA's WISE, Fermi missions reveal a surprising
blazar connection.»
A blazar appears bright to Fermi for two reasons.
They say the electrons, protons and other particles accelerated in
blazar jets leave a specific «fingerprint» in the infrared light they emit.
At the heart of
a blazar lies a supersized black hole with millions of times the sun's mass surrounded by a disk of hot gas and dust.
The infrared / gamma - ray connection led the authors to search for new
blazar candidates among WISE infrared sources located within the positional uncertainties of Fermi's unidentified gamma - ray objects.
A blazar, a galaxy that kicks out fluctuating X-rays, might also have been responsible, but blazars are easily identified by their strong radio emissions, something not apparent in this source (Nature, DOI: 10.1038 / nature08083).
In the second half of last year
the blazar CTA 102, which is 7,600 million light years from Earth, brightened considerably, drawing the attention of all the astronomers who specialise in this kind of objects.
This event was so exceptional that for a few days this object was the brightest
blazar observed until now.
Black - hole - powered galaxies called
blazars are the most common sources detected by NASA's Fermi Gamma - ray Space Telescope.
Astronomers suspect many of these are
blazars, but there isn't enough information to classify them.
In 2011, Massaro, D'Abrusco and their colleagues began using WISE data to investigate Fermi
blazars.
The relationship effectively connects the dots for
blazars across an enormous swath of the electromagnetic spectrum.
Francesco Massaro at the University of Turin in Italy and Raffaele D'Abrusco at the Harvard - Smithsonian Center for Astrophysics in Cambridge, Massachusetts, show for the first time that the mid-infrared colors of
blazars in WISE data correlate to an equivalent measurement of their gamma - ray output.
«We found that when we plotted Fermi
blazars by their WISE colors in a particular way, they occupied a distinctly different part of the plot than other extragalactic gamma - ray sources.»
They could have emerged from gamma - ray bursts, mysterious and short - lived cataclysms that briefly rank as the brightest objects in the universe; shock waves from exploding stars; or so - called
blazars, jets of energy powered by supermassive black holes.
The High Altitude Water Cherenkov observatory has released its first map of the high - energy sky, catching pulsars, supernova remnants and
blazars switching on and off
Gamma rays emanate from the most powerful and mysterious phenomena in the universe — quasars, supernovae, and the black hole - powered infernos called
blazars.
Fermi has shown that much of this light arises from unresolved gamma - ray sources, particularly galaxies called
blazars, which are powered by material falling toward gigantic black holes.
In a detailed analysis of high - energy EGB gamma rays, published April 14 in Physical Review Letters, Ajello and his team show that
blazars and other discrete sources can account for nearly all of this emission.
It turns out that
blazars are powered surprisingly like the exhausts of jet engines, albeit on a cosmic scale, says astronomer and lead author Alan Marscher of Boston University.
The galaxy is among about 1,800
blazars that Readhead and his team have observed twice a week since 2008.
Bright spots in the map include the Crab Nebula, which hosts a radiation - spewing stellar corpse called a pulsar, and several
blazars, violent active galaxies where colossal black holes accelerate particles to more than 99 % the speed of light.
Blazars — found in the centers of some galaxies — and gamma - ray bursts are two identified wellsprings of these high - energy rays.
Blazars periodically flare when the supermassive black holes in some active galaxies» cores fill with dust and gas, releasing massive amounts of energy.