* Astronomy

This time ten years ago, two independent teams of researchers in the US were deliberating over whether to go public with a discovery that would change our view of the universe forever. It concerned observations of distant supernovae that appeared to be moving away from each other faster than they should have been. A few weeks later the world found out that the expansion of the universe is accelerating, probably driven by some kind of gravitationally repulsive dark energy that makes up 75% of the universe.

Source

Cosmologists have run a series of huge computer simulations of the Universe that could ultimately help solve the mystery of dark energy.
Results of the simulations, carried out by Durham Universitys world-leading Institute for Computational Cosmology (ICC), tell researchers how to measure dark energy a repulsive force that counteracts gravity.
The findings, published today (Friday, January 11) in the Monthly Notices of the Royal Astronomical Society, will also provide vital input into the design of a proposed satellite mission called SPACE the SPectroscopic All-sky Cosmic Explorer - that could unveil the nature of dark energy.
The discovery of dark energy in 1998 was completely unexpected and understanding its nature is one of the biggest problems in physics.
Scientists believe dark energy, which makes up 70 per cent of the Universe, is driving its accelerating expansion. If this expansion continues to accelerate experts say it could eventually lead to a Big Freeze as the Universe is pulled apart and becomes a vast cold expanse of dying stars and black holes.
The Durham research was funded by the Science and Technology Facilities Council and the European Commission
The simulations, which took 11 days to run on Durhams unique Cosmology Machine (COSMA) computer, looked at tiny ripples in the distribution of matter in the Universe made by sound waves a few hundred thousand years after the Big Bang.
The ripples are delicate and some have been destroyed over the subsequent 13 billion years of the Universe, but the simulations showed they survived in certain conditions.
By changing the nature of dark energy in the simulations, the researchers discovered that the ripples appeared to change in length and could act as a standard ruler in the measurement of dark energy.

The ripples are a gold standard. By comparing the size of the measured ripples to the gold standard we can work out how the Universe has expanded and from this figure out the properties of the dark energy. Astronomers are stuck with the one universe we live in. However, the simulations allow us to experiment with what might have happened if there had been more or less dark energy in the universe - Carlos Frenk, ICC Director Professor.

In the next five to 10 years a number of experiments are planned to explore dark energy. The Durham simulation has demonstrated the feasibility of the SPACE satellite mission proposed to the European Space Agencys (ESA) Cosmic Vision programme.
The project has been put forward by an international consortium of researchers including the Durham team.
SPACE, which is led by Bologna University, in Italy, is through to the next round of assessment by the ESA and if successful is planned to launch in 2017.

Thanks to the ICC simulations it is possible to predict what SPACE would observe and to plan how to develop the mission parameters in order to obtain a three-dimensional map of the Universe and to compare it with the predictions of the simulations. Thanks to this comparison it will be possible to unveil the nature of dark energy and to understand how the structures in the Universe built up and evolved with cosmic time - Co-principal investigator Professor Andrea Cimatti, of Bologna University.

Source

-- Edited by Blobrana at 10:07, 2008-01-11

It might seem as if astronomers and astrophysicists have had enormous success at unlocking the mysteries of space.
Impressive evidence has been gathered to support the theory that our universe was created about 13.7 billion years ago with an explosion of energy that eventually formed the innumerable galaxies still spinning away from one another to uncharted expanses of space.
We've discovered distant planets that might be friendly to life as we know it and have estimated distances to remote pulsing stars to help map the universe. We've assessed the power of black holes and remain awestruck by the extraordinary beauty of images of distant galaxies, young and old, captured by the Hubble Space Telescope.
But central mysteries of the universe remain unsolved, and from a scientific viewpoint, there are still more questions than answers. Most scientists would agree that we know very little about what really makes up our universe - and little about its origin and possible fate.

Read more

Have we hastened the demise of the universe by looking at it? Thats the startling question posed by a pair of physicists, who suggest that we may have accidentally nudged the universe closer to its death by observing dark energy, which is thought to be speeding up cosmic expansion.
Lawrence Krauss of Case Western Reserve University in Cleveland, Ohio, and colleague James Dent suggest that by making this observation in 1998 we may have caused the universe to revert to a state similar to early in its history, when it was more likely to end.

Incredible as it seems, our detection of the dark energy may have reduced the life-expectancy of the universe - Lawrence Krauss.

The researchers came to their conclusion by calculating how the energy state of our universe might have evolved. Until recently, cosmologists thought that the big bang 13.7 billion years ago occurred after a bubble of weird high-energy false vacuum with repulsive gravity decayed into a zero-energy ordinary vacuum. The energy released during this transition could have made matter and heated it to a ferocious temperature, which essentially created the massive explosion of the big bang. The discovery of dark energy - and the realisation that the universes expansion is accelerating - reveals that the vacuum may not have decayed to zero energy, but to another false vacuum state. In other words, some energy was retained in this vacuum, and this is accelerating the universes expansion.

Source