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Supercomputer
Simulation Of Universe Expected To Help In Search For Missing
Matter
Thursday, December 6, 2007
Pictured
is a portion of a supercomputer simulation of the universe
showing a region roughly 1.5 billion light-years on a side.
The bright object in the center is a galaxy cluster about 1
million-billion times the mass of the sun. In between the
filaments, which store most of the universe's mass, are
giant, spherical voids nearly empty of matter.
(Click
image for larger version)
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Credit:
University
of Colorado at Boulder
Much of the gaseous mass of
the universe is bound up in a tangled web of cosmic filaments
that stretch for hundreds of millions of light-years, according
to a new supercomputer study by a team led by the University of
Colorado at Boulder.
The study indicated a significant
portion of the gas is in the filaments -- which connect galaxy
clusters -- hidden from direct observation in enormous gas clouds
in intergalactic space known as the Warm-Hot Intergalactic
Medium, or WHIM, said CU-Boulder Professor Jack Burns of the
astrophysical and planetary sciences department. The team
performed one of the largest cosmological supercomputer
simulations ever, cramming 2.5 percent of the visible universe
inside a computer to model a region more than 1.5 billion
light-years across. One light-year is equal to about six trillion
miles.
A paper on the subject will be published in the
Dec. 10 issue of the Astrophysical Journal. In addition to Burns,
the paper was authored by CU-Boulder Research Associate Eric
Hallman of APS, Brian O'Shea of Los Alamos National Laboratory,
Michael Norman and Rick Wagner of the University of California,
San Diego and Robert Harkness of the San Diego Supercomputing
Center.
It took the researchers nearly a decade to
produce the extraordinarily complex computer code that drove the
simulation, which incorporated virtually all of the known
physical conditions of the universe reaching back in time almost
to the Big Bang, said Burns. The simulation -- which uses
advanced numerical techniques to zoom-in on interesting
structures in the universe -- modeled the motion of matter as it
collapsed due to gravity and became dense enough to form cosmic
filaments and galaxy structures.
"We see this as a
real breakthrough in terms of technology and in scientific
advancement," said Burns. "We believe this effort
brings us a significant step closer to understanding the
fundamental constituents of the universe."
According
to the standard cosmological model, the universe consists of
about 25 percent dark matter and 70 percent dark energy around 5
percent normal matter, said Burns. Normal matter consists
primarily of baryons - hydrogen, helium and heavier elements --
and observations show that about 40 percent of the baryons are
currently unaccounted for. Many astrophysicists believe the
missing baryons are in the WHIM, Burns said.
"In the
coming years, I believe these filaments may be detectable in the
WHIM using new state-of-the-art telescopes," said Burns, who
along with Hallman is a fellow at CU-Boulder's Center for
Astrophysics and Space Astronomy. "We think that as we begin
to see these filaments and understand their nature, we will learn
more about the missing baryons in the universe."
Two
of the key telescopes that astrophysicists will use in their
search for the WHIM are the 10-meter South Pole Telescope in
Antarctica and the 25-meter Cornell-Caltech Atacama Telescope, or
CCAT, being built in Chile's Atacama Desert, Burns said.
CU-Boulder scientists are partners in both observatories.
The
CCAT telescope will gather radiation from sub-millimeter
wavelengths, which are longer than infrared waves but shorter
than radio waves. It will enable astronomers to peer back in time
to when galaxies first appeared -- just a billion years or so
after the Big Bang -- allowing them to probe the infancy of the
objects and the process by which they formed, said Burns.
The
South Pole Telescope looks at millimeter, sub-millimeter and
microwave wavelengths of the spectrum and is used to search for,
among other things, cosmic microwave background radiation - the
cooled remnants of the Big Bang, said Burns. Researchers hope to
use the telescopes to estimate heating of the cosmic background
radiation as it travels through the WHIM, using the radiation
temperature changes as a tracer of sorts for the massive
filaments.
The CU-Boulder-led team ran the computer code
for a total of about 500,000 processor hours at two
supercomputing centers --the San Diego Supercomputer Center and
the National Center for Supercomputing Applications at the
University of Illinois at Urbana-Champaign. The team generated
about 60 terabytes of data during the calculations, equivalent to
three-to-four times the digital text in all the volumes in the
U.S. Library of Congress, said Burns.
Burns said the
sophisticated computer code used for the universe simulation is
similar in some respects to a code used for complex supercomputer
simulations of Earth's atmosphere and climate change, since both
investigations focus heavily on fluid dynamics.
The
Astrophysical Journal study was funded by NASA, the National
Science Foundation and the U.S. Department of Energy through the
Los Alamos National Laboratory.
Source:
University of Colorado at Boulder
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