This artist's concept illustrates a
supermassive black hole with millions to billions times the mass of our
sun. Supermassive black holes are enormously dense objects buried at the
hearts of galaxies. Image credit: NASA/JPL-Caltech
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Black Holes: Monsters in Space
This artist's concept illustrates a supermassive black hole with millions to billions times the mass of our sun. Supermassive black holes are enormously dense objects buried at the hearts of galaxies. (Smaller black holes also exist throughout galaxies.) In this illustration, the supermassive black hole at the center is surrounded by matter flowing onto the black hole in what is termed an accretion disk. This disk forms as the dust and gas in the galaxy falls onto the hole, attracted by its gravity.Also shown is an outflowing jet of energetic particles, believed to be powered by the black hole's spin. The regions near black holes contain compact sources of high energy X-ray radiation thought, in some scenarios, to originate from the base of these jets. This high energy X-radiation lights up the disk, which reflects it, making the disk a source of X-rays. The reflected light enables astronomers to see how fast matter is swirling in the inner region of the disk, and ultimately to measure the black hole's spin rate.
Image credit: NASA/JPL-Caltech
Scientists measure the spin rates of
supermassive black holes by spreading the X-ray light into different
colors. Image credit: NASA/JPL-Caltech
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› Full SizeTwo Models of Black Hole Spin
Scientists measure the spin rates of supermassive black holes by spreading the X-ray light into different colors. The light comes from accretion disks that swirl around black holes, as shown in both of the artist's concepts. They use X-ray space telescopes to study these colors, and, in particular, look for a "fingerprint" of iron -- the peak shown in both graphs, or spectra -- to see how sharp it is. Prior to observations with NASA's Spectroscopic Telescope Array, or NuSTAR, and the European Space Agency's XMM-Newton telescope, there were two competing models to explain why this peak might not appear to be sharp.The "rotation" model shown at top held that the iron feature was being spread out by distorting effects caused by the immense gravity of the black hole. If this model were correct, then the amount of distortion seen in the iron feature should reveal the spin rate of the black hole.
The alternate model held that obscuring clouds lying near the black hole were making the iron line appear artificially distorted. If this model were correct, the data could not be used to measure black hole spin.
NuSTAR helped to solve the case, ruling out the alternate "obscuring cloud" model. Its high-energy X-ray data -- shown at top as green bump to the right of the peak -- revealed that features in the X-ray spectrum are in fact coming from the accretion disk and not from the obscuring clouds. Together with XMM-Newton, the space observatories were able to make the first conclusive measurement of a black hole's spin rate, and more generally, confirm that the "gravitational distortion" model is accurate.
Image credit: NASA/JPL-Caltech
PASADENA, Calif. -- Two X-ray space observatories, NASA's Nuclear
Spectroscopic Telescope Array (NuSTAR) and the European Space Agency's
XMM-Newton, have teamed up to measure definitively, for the first time,
the spin rate of a black hole with a mass 2 million times that of our
sun.
The supermassive black hole lies at the dust- and gas-filled heart of a
galaxy called NGC 1365, and it is spinning almost as fast as Einstein's
theory of gravity will allow. The findings, which appear in a new study
in the journal Nature, resolve a long-standing debate about similar
measurements in other black holes and will lead to a better
understanding of how black holes and galaxies evolve.
"This is hugely important to the field of black hole science," said Lou
Kaluzienski, a NuSTAR program scientist at NASA Headquarters in
Washington.
The observations also are a powerful test of Einstein's theory of
general relativity, which says gravity can bend space-time, the fabric
that shapes our universe, and the light that travels through it.
"We can trace matter as it swirls into a black hole using X-rays emitted
from regions very close to the black hole," said the coauthor of a new
study, NuSTAR principal investigator Fiona Harrison of the California
Institute of Technology in Pasadena. "The radiation we see is warped and
distorted by the motions of particles and the black hole's incredibly
strong gravity."
NuSTAR, an Explorer-class mission launched in June 2012, is designed to
detect the highest-energy X-ray light in great detail. It complements
telescopes that observe lower-energy X-ray light, such as XMM-Newton and
NASA's Chandra X-ray Observatory. Scientists use these and other
telescopes to estimate the rates at which black holes spin.
Until now, these measurements were not certain because clouds of gas
could have been obscuring the black holes and confusing the results.
With help from XMM-Newton, NuSTAR was able to see a broader range of
X-ray energies and penetrate deeper into the region around the black
hole. The new data demonstrate that X-rays are not being warped by the
clouds, but by the tremendous gravity of the black hole. This proves
that spin rates of supermassive black holes can be determined
conclusively.
"If I could have added one instrument to XMM-Newton, it would have been a
telescope like NuSTAR," said Norbert Schartel, XMM-Newton Project
Scientist at the European Space Astronomy Center in Madrid. "The
high-energy X-rays provided an essential missing puzzle piece for
solving this problem."
Measuring the spin of a supermassive black hole is fundamental to understanding its past history and that of its host galaxy.
"These monsters, with masses from millions to billions of times that of
the sun, are formed as small seeds in the early universe and grow by
swallowing stars and gas in their host galaxies, merging with other
giant black holes when galaxies collide, or both," said the study's lead
author, Guido Risaliti of the Harvard-Smithsonian Center for
Astrophysics in Cambridge, Mass., and the Italian National Institute for
Astrophysics.
Supermassive black holes are surrounded by pancake-like accretion disks,
formed as their gravity pulls matter inward. Einstein's theory predicts
the faster a black hole spins, the closer the accretion disk lies to
the black hole. The closer the accretion disk is, the more gravity from
the black hole will warp X-ray light streaming off the disk.
Astronomers look for these warping effects by analyzing X-ray light
emitted by iron circulating in the accretion disk. In the new study,
they used both XMM-Newton and NuSTAR to simultaneously observe the black
hole in NGC 1365. While XMM-Newton revealed that light from the iron
was being warped, NuSTAR proved that this distortion was coming from the
gravity of the black hole and not gas clouds in the vicinity. NuSTAR's
higher-energy X-ray data showed that the iron was so close to the black
hole that its gravity must be causing the warping effects.
With the possibility of obscuring clouds ruled out, scientists can now
use the distortions in the iron signature to measure the black hole's
spin rate. The findings apply to several other black holes as well,
removing the uncertainty in the previously measured spin rates.
For more information on NASA's NuSTAR mission, visit: http://www.nasa.gov/nustar .
For more information on ESA's XMM-Newton mission, visit: http://go.nasa.gov/YUYpI6 .
The California Institute of Technology in Pasadena manages JPL for NASA.
Whitney Clavin 818-354-4673
Jet Propulsion Laboratory, Pasadena, Calif.
whitney.clavin@jpl.nasa.gov
J.D. Harrington 202-358-5241
NASA Headquarters, Washington
j.d.harrington@nasa.gov
Jet Propulsion Laboratory, Pasadena, Calif.
whitney.clavin@jpl.nasa.gov
J.D. Harrington 202-358-5241
NASA Headquarters, Washington
j.d.harrington@nasa.gov
NASA
Guillermo Gonzalo Sánchez Achutegui
ayabaca@hotmail.com
ayabaca@gmail.com
ayabaca@yahoo.com
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