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Chandra Looks Over a Cosmic
Four-Leaf Clover
A careful analysis of observations by NASA’s Chandra
X-ray Observatory of a rare quadruple quasar has uncovered evidence that
possibly a single star in a foreground galaxy magnified X-rays
coming from the quasar. This discovery gives astronomers a new
and extremely precise probe of the gas flow around the supermassive
black hole that powers the quasar. “If our interpretation
is correct, then we are seeing details around this black hole that
are 50,000 times smaller than either the Hubble
Space Telescope or Chandra could see under ordinary circumstances,” said
George Chartas, an astronomer at Penn
State University in University
Park and the lead author of a recent article on the Cloverleaf
quasar in The Astrophysical
Journal.
The Cloverleaf quasar is a
single object about 11 billion light years from Earth that appears
as four images produced by a process known as gravitational lensing.
If one or more galaxies lie along the line of sight to a more distant
quasar, the gravitational field of the intervening galaxies can
bend and magnify the light from the quasar and produce multiple
images of it. The four images of the Cloverleaf quasar have been
produced by one or more intervening galaxies.
One of the images
(A), in the Cloverleaf is brighter than the others in both optical
and X-ray light. Chartas and his colleagues found the relative
brightness of this image was greater in X-ray than in optical
light. The X-rays from iron atoms also were enhanced relative to
X-rays at lower energies. Since the amount of brightening due to
gravitational lensing does not vary with the wavelength, this means
that an additional object has magnified the X-rays.
The increased magnification of
the X-ray light can be explained by gravitational microlensing,
an effect that has been used to search for compact stars and planets
in our galaxy. Microlensing occurs when a star or a multiple star
system passes in front of light from a background object. If a
single star or a multiple star system in one of the foreground
galaxies passed in front of the light path for the brightest image,
then that image would be selectively magnified. The X-rays would
be magnified much more than the visible light, if they came from
a smaller region around the black hole than the visible light.
The enhancement of the X-rays from iron ions would be due to this
same effect.
The analysis indicates that the X-rays are coming from a very small
region, about the size of the solar system, around the supermassive
black hole. The visible light is coming from a region ten or more
times larger. The angular size of these regions at a distance of
11-billion light years is tens of thousands times smaller than
the smallest region that can be resolved by the Hubble Space Telescope.
“The
significance of the detection of microlensed X-rays from the Cloverleaf
quasar lies in the extremely small region that is enhanced by the
microlens,” said Chartas. “This gives
us the ability to make strong tests of models for the flow of gas
around a supermassive black hole.”
Other team members include Michael
Eracleous of Penn State, Eric
Agol of the University of
Washington, and Sarah Gallagher of
the University of California at
Los Angeles. NASA’s Marshall
Space Flight Center in Huntsville, Alabama, manages the Chandra
program for NASA’s Office
of Space Science in Washington,
D.C. Northrop Grumman of Redondo Beach, California, formerly TRW,
Inc., was the prime development contractor for the observatory.
The Smithsonian
Astrophysical Observatory controls science and
flight operations from the Chandra
X-ray Center in Cambridge, Massachusetts.
Megan
Watzke, Chandra X-ray Observatory Center
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