LAST week scientists at CERN, Europe's main particle-physics lab, finally ran the Higgs boson to ground. The discovery of the Higgs,
whose existence was first predicted in 1964, is a powerful
demonstration of the predictive powers of the Standard Model of particle
physics. But other scientists have powerful theories of their own, even
if they get less press than particle physicists do. A paper just
published in the Monthly Notices of the Royal Astronomical Society reports another predictive triumph, this time for astronomers.
Sebastiano
Cantalupo, of the University of California, Santa Cruz, and his
colleagues may have become the first people ever to spot "dark
galaxies", the antediluvian ancestors of the bright islands that contain
almost all of the stars in the modern universe, and of which Earth's
own Milky Way is one.
Despite their name, dark galaxies are not as tenebrous as other "dark" astronomical phenomena. Unlike dark energy or exotic dark matter—so
called because, since they do not interact with photons of
electromagnetism, their presence can only be discerned through their
gravitational effects—they are made up of humdrum hydrogen and helium
gas. But they are relatively small, and their weak gravity means their
gas is so dispersed that stars condense out of it only very slowly.
Some
characteristics of bigger, brighter, modern galaxies—for example, the
relationship between a galaxy's mass and its star-formation rate—could
be explained if there are sources of gas feeding them. Dark galaxies
could fit the bill. Astronomers think that their sluggishness at
converting gas into stars meant that they remained gaseous while the
earliest generations of stars formed, becoming, in effect, leftover
stockpiles of gas that more active galaxies could tap. And although none
has been observed until now, they were independently predicted by
theoretical models that describe how the various forms of large-scale
structure visible in today's universe—galaxies, clusters, superclusters
and the enormous, thread-like structures called filaments—condensed out
of tiny fluctuations within the thin, almost uniform soup of the early
universe.
All this has meant that scientists were relatively
confident dark galaxies must have existed. But their predicted dimness
was always going to make them hard to pin down. Like their
particle-physicist comrades, then, Dr Cantalupo and his team required
cutting-edge kit to perform their search. They used a custom-built
filter attached to the European Southern Observatory's Very Large
Telescope (VLT).
Despite having a name even more prosaic than CERN's
Large Hadron Collider, where the Higgs discovery was made, the VLT
(pictured) is one of the most powerful optical telescopes in the world.
Given
that dark galaxies give off almost no light, the researchers used their
filter to look for something else that might, literally, shed light
onto their cosmic quarry. In this case, the source of illumination was a
nearby quasar. The ultraviolet radiation from this very bright and
distant galactic nucleus (HE0109-3518, for the curious) caused the gas
in the proto-galaxy to fluoresce.
After controlling for various
sorts of false positives, the astronomers were left with a dozen strong
candidates, each with about a billion times the mass of the sun and a
rate of star formation around 200 times lower than a more familiar
spiral galaxy—just as predicted. One for the astronomers, then, just so
the particle physicists don't get too smug.
No comments:
Post a Comment