Astronomers have measured the precise distance to over a quarter of a million galaxies to gain new insights into a key period in cosmic history.
Astronomers have measured the precise distance to over a quarter
of a million galaxies to gain new insights into a key period in cosmic history.
The 3D map of the sky
allows scientists to probe the time six billion years ago when dark energy
became the dominant influence on the Universe's expansion.
No-one knows the true
nature of this repulsive force, but the exquisite data in the international BOSS survey will help
test various theories.
The analysis appears
in six papers.
These have all been
posted on the arXiv preprint server.
"This is an
incredibly exciting time to be working in cosmology, and we're all privileged
to be part of the Baryon Oscillation Spectroscopic Survey (BOSS)," said
Prof Will Percival from the University of Portsmouth - a UK member of the
international research group.
"What we've done
is measure the 3D positions for just over 250,000 galaxies, covering the
largest volume of the Universe ever surveyed. That gives us an amazing map that
we can then analyse to try to understand how and why the Universe's expansion
is accelerating," he told BBC News.
Prof Percival was
speaking here in Manchester at the UK National
Astronomy Meeting (NAM).
Preferred separation
The discovery that
everything in the cosmos is moving apart at a faster and faster rate was one of the major
breakthroughs of the 20th Century.
It went against all
preconceptions. Up until the discovery, it was thought the Universe's expansion
would most likely have been decelerating under the influence of gravity.
Scientists now find
themselves grasping for new physics to try to explain what is going on.
BOSS is intended to
support that effort.
It uses two techniques
to understand the acceleration.
One concerns so-called
baryon acoustic
oscillations. These are pressure-driven waves that passed
through the very early Universe and which were imprinted on the distribution of
matter once conditions had cooled below a certain point.
Today, these
"wiggles" show themselves as a preferred scale in the separation of
galaxies and can be used as a kind of standard ruler to measure the geometry of
the cosmos.
"Because you can
trace this pattern all the way through the Universe, it tells you a lot about
its content," explained Portsmouth's Dr Rita Tojeiro.
"If it had a
different content - it had more matter, or it had less matter, or it had been
expanding at a different rate - then you'd see a different map of the galaxies.
So, the fundamental observation is this map."
Einstein 'right'
The other technique
being used by BOSS involves "redshift space distortions". These
describe the component in the velocity of galaxies that stems from the growth
of structure in the Universe. The team can see if neighbouring galaxies are
clustering in the way that would be expected from the action of gravity.
"What we find is
everything is very consistent with Einstein's theory of general relativity,
coupled with the cosmological constant that he put into his equations. He put
it in originally to make the Universe static, and then took it out.
"But if we put
constant in with the opposite sign, we can get acceleration. And if we do that,
we find equations that are perfectly consistent with what we're seeing."
The quality of the
BOSS map is big step forward on all previous such surveys.
It provides details on
the position of galaxies out to some six billion light-years from Earth and
gives those measurements to within 1.7% of their expected true value.
This is particularly
significant in the context of understanding dark energy because six billion
years ago is the period when the repulsive force becomes the dominant action in
driving the expansion of the Universe, and gravity takes a back seat.
Space mission
The BOSS project,
which acquires all its data using the 2.5m Sloan telescope at Apache Point
Observatory in New Mexico, is only a third complete and will
continue to map the 3D positions of galaxies.
"We use these
measurements to test a whole bunch of theories to try to understand dark energy
a little bit better," Dr Tojeiro told BBC News.
"The better your
measurement, the more discriminant power you have between those competing
theories. And if we can get an even greater volume of galaxies then we can
start to perform new and different tests."
The European Space
Agency is also planning to take the BOSS approach into orbit with its Euclid mission,
which should launch towards the end of the decade. Portsmouth researchers will
be playing key roles in the space mission, also.
Euclid will measure
the precise positions of 50 million galaxies out to some 10 billion light-years
from Earth.
This means it will
witness the full evolution of dark energy's influence on the expansion, from
minimal relevance at the earliest epoch to its overriding control in modern
times.