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STS-126: The programs

In advance of shuttle Endeavour's STS-126 mission to the station, managers from both programs discuss the flight.

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STS-126: The mission

A detailed preview of Endeavour's mission to deliver expanded crew accommodations to the station is provided in this briefing.

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STS-126: Spacewalks

Four spacewalks are planned during Endeavour's STS-126 mission to the station.

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STS-126: The Crew

The Endeavour astronauts, led by commander Chris Ferguson, meet the press in the traditional pre-flight news conference.

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Mercury science

Scientists present imagery and instrument data collected by the MESSENGER spacecraft during its second flyby of the planet Mercury.

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Shuttle rollaround

Space shuttle Endeavour switched launch pads on Oct. 23, traveling from pad 39B to pad 39A.

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Chandrayaan 1

India launches its first lunar orbiter, the Chandrayaan 1 spacecraft, from the country's Satish Dhawan Space Center.

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Shuttle rollback

Atlantis was moved off pad 39A and placed inside the Vehicle Assembly Building for storage to wait out the Hubble mission delay.

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IBEX launch

A Pegasus rocket carrying NASA's Interstellar Boundary Explorer launches over the Pacific Ocean.

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Giant simulation could solve mystery of 'dark matter'
DURHAM UNIVERSITY NEWS RELEASE
Posted: November 11, 2008

The search for a mysterious substance which makes up most of the Universe could soon be at an end, according to new research.

Dark matter is believed to account for 85 percent of the Universe's mass but has remained invisible to telescopes since scientists inferred its existence from its gravitational effects more than 75 years ago.

Now the international Virgo Consortium, a team of scientists including cosmologists at Durham University, has used a massive computer simulation showing the evolution of a galaxy like the Milky Way to "see" gamma-rays given off by dark matter.

They say their findings, published in the prestigious scientific journal Nature (Thursday, November 6), could help NASA's Fermi Telescope in its search for the dark matter and open a new chapter in our understanding of the Universe.

The Virgo Consortium looked at dark matter halos - structures surrounding galaxies - which contain a trillion times the mass of the Sun.

Their simulations - called The Aquarius Project - showed how the galaxy's halo grew through a series of violent collisions and mergers between much smaller clumps of dark matter that emerged from the Big Bang.

The researchers found that gamma-rays produced when particles collided in areas of high dark matter density could be most easily detectable in regions of the Milky Way lying close to the Sun in the general direction of the galaxy's centre.

They suggest the Fermi Telescope should search in this part of the galaxy where they predict that gamma-rays from dark matter should glow in "a smoothly varying and characteristic pattern".

If Fermi does detect the predicted emission from the Milky Way's smooth inner halo the Virgo team believes it might be able to see otherwise invisible clumps of dark matter lying very close to the Sun.

The Virgo research involved scientists from the Max Planck Institute for Astrophysics in Germany, The Institute for Computational Cosmology at Durham University, UK, the University of Victoria in Canada, the University of Massachusetts, USA, and the University of Groningen in the Netherlands.

Professor Carlos Frenk, Director of the Institute for Computational Cosmology, at Durham University, said: "Solving the dark matter riddle will be one of the greatest scientific achievements of our time.

"The search for dark matter has dominated cosmology for many decades. It may soon come to an end."

Professor Simon White, Director of the Max Planck Institute for Astrophysics, said: "These calculations finally allow us to 'see' what the dark matter distribution should look like near the Sun where we might stand a chance of detecting it."

Dr Volker Springel, of the Max Planck Institute for Astrophysics, led the computer simulations which took 3.5 million processor hours to complete.

Dr Springel said: "This calculation has redefined the state of the art in cosmological simulations. At times I thought it would never end."

The research was funded by the Max Planck Society, the Bavarian Computing Centre, a Royal Society Wolfson Research Merit Award and the Science and Technology Facilities Council.