In Distant Galaxies, New Clues to Century-Old Molecule Mystery
A team of NASA and European scientists recorded the "fingerprints" of mystery molecules - thought to be large organic compounds - in two distant galaxies...
In a study that pushes the limits of observations currently possible from Earth,
a team of NASA and European scientists recorded the "fingerprints" of mystery
molecules in two distant galaxies, Andromeda and the Triangulum. Astronomers can
count on one hand the number of galaxies examined so far for such fingerprints,
which are thought to belong to large organic molecules, says the team's leader,
Martin Cordiner of the Goddard Center for Astrobiology at NASA's Goddard Space
Flight Center in Greenbelt, Md.
Figuring out exactly which molecules are
leaving these clues, known as "diffuse interstellar bands" (DIBs), is a puzzle
that initially seemed straightforward but has gone unsolved for nearly a hundred
years. The answer is expected to help explain how stars, planets and life form,
so settling the matter is as important to astronomers who specialize in
chemistry and biology as determining the nature of dark matter is to the
specialists in physics.
Cordiner is presenting the team's research at the
American Astronomical Society meeting in Seattle, Wash., on Jan. 10, 2011, and
the results from Andromeda were published in an Astrophysical Journal paper on
Jan. 1. The findings provide some evidence against one of the top candidates on
the list of suspects: polycyclic aromatic hydrocarbons (PAHs), a group of
molecules that is widespread in space. The research also reveals that some of
the signatures found in Andromeda and the Triangulum are similar to ones seen in
our own Milky Way, despite some big differences between those galaxies and
ours.
"We have studied DIBs in incredibly diverse environments. Some have
low levels of UV radiation. Some have radiation levels thousands of times
higher. Some have different amounts of 'ingredients' available for making stars
and planets," Cordiner says. "And throughout all of these, we see
DIBs."
Missing in action
Until now, only two galaxies
beyond our own have been investigated in detail for DIBs. Those are our nearest
neighbors, the Large and Small Magellanic Clouds, which lie 160,000 to 200,000
light years away. (Researchers have conducted selective studies elsewhere,
however.)
Andromeda and the Triangulum are located much farther away, at
about 2.5 to 3 million light years from Earth. "At those distances, individual
stars are so faint that we need to push even the largest telescopes in the world
to their limits in order to observe them," Cordiner says.
That statement
might seem strange to anyone who has looked into the night sky and seen either
of these galaxies with the naked eye. Under favorable conditions, the galaxies
appear as smudges in the constellations that bear their respective
names.
But to study DIBs, researchers need to do much more than see that
the galaxy is there. They have to pick out individual stars within the galaxy,
and only a few telescopes worldwide are powerful enough to gather sufficient
light for that. (The team used the Gemini Observatory's telescope in Hawaii.)
This is why most DIBs found so far have been in the Milky Way.
Whichever
galaxy an astronomer chooses, though, it will be made up of tens to hundreds of
billions of stars. "The first step is choosing which stars to observe," Cordiner
explains.
Cordiner's colleagues at Queen's University in Belfast, U.K.,
took the lead on finding good targets. They picked blue supergiants—stars that
are very large, very hot and very bright. Supergiants also burn very clean:
unlike our sun and other cooler stars, they contribute little background clutter
to the observations being made.
To look for DIBs, an astronomer points
the telescope at a star and scans through a rainbow made up of thousands of
wavelengths of light. This rainbow, or spectrum, is extended a bit beyond
visible light, into the UV at the blue end and into the infrared at the red
end.
DIBs are not defined by what astronomers see while doing this, but
by what they don't see. The colors missing from the rainbow, marked by black
stripes, are the ones of interest. Each one is a wavelength being absorbed by
some kind of atom or molecule.
A DIB is one of these regions where the
color is missing. But compared to the nice, neat "absorption lines" that are
identified with atoms or simple molecules, a DIB is not well-behaved, which is
why it stands out.
"Astronomers were used to seeing quite sharp, narrow
bands where typical atoms and molecules absorb," says Cordiner. "But DIBs are
broad; that's why they are called 'diffuse.' Some DIBs have simple shapes and
are quite smooth, but others have bumps and wiggles and may even be
lopsided."
The mystery deepens
Over time, astronomers have
been building up catalogs to show exactly which wavelengths are absorbed by all
kinds of atoms and molecules. Each molecule has its own unique pattern, which
can be used like a fingerprint: if a pattern found during an astronomical
observation matches a pattern in one of the catalogs, the molecule can be
identified.
It's a pretty straightforward concept. So, early researchers
"would surely not have thought that the solution to the diffuse band problem
would still be so elusive," wrote Peter Sarre in a 2006 review article about
DIBs. Sarre, a professor of chemistry and molecular astrophysics at the
University of Nottingham, U.K., supervised Cordiner's graduate-school work on
DIBs.
The significance of the first DIBs, recorded in 1922 in Mary Lea
Heger's Ph.D. thesis, was not immediately recognized. But once astronomers began
systematic studies, starting with a 1934 paper by P. W. Merrill, they had every
reason to believe the problem could be solved within a decade or
two.
No such luck
More than 400 DIBs have been documented
since then. But not one has been identified with enough certainty for
astronomers to consider its case closed.
"With this many diffuse bands,
you'd think we astronomers would have enough clues to solve this problem," muses
Joseph Nuth, a senior scientist with the Goddard Center for Astrobiology who was
not involved in this work. "Instead, it's getting more mysterious as more data
is gathered."
Detailed analyses of the bumps and wiggles of the DIBs,
suggest that the molecules which give rise to DIBs—called "carriers"—are
probably large.
But like beauty, "large" is in the eye of the beholder.
In this case, it means the molecule has at least 20 atoms or more. This is quite
small compared to, say, a protein but huge compared to a molecule of carbon
monoxide, a very common molecule in space.
Recently, though, more
interest has been focused on at least one small molecule, a chain made from
three carbon atoms and two hydrogen atoms (C3H2). This was tentatively
identified with a pattern of DIBs.
Tenacious D
On the list
of DIB-related suspects, all molecules have one thing in common: they are
organic, which means they are built largely from carbon.
Carbon is great
for building large numbers of molecules because it is available almost
everywhere. In space, only hydrogen, helium and oxygen are more plentiful. Here
on Earth, we find carbon in the planet's crust, the oceans, the atmosphere and
all forms of life.
Likewise, astronomers "see DIBs pretty much in any
direction we look," says Jan Cami, an astronomer at the University of Western
Ontario, Canada. He has collaborated with Cordiner before but was not involved
in this study. "And we see lots of DIBs."
Carbon is also great for
building molecules in all kinds of configurations—millions of carbon compounds
have been identified—and especially for building very stable
molecules.
DIB carriers also seem to be quite stable. They survive the
harsh physical conditions in the interstellar medium—the material found in the
space between the stars. They also hang tough in the Large Magellanic Cloud,
where radiation levels are thousands of times stronger than in the Milky Way. In
fact, says Cordiner, DIB carriers seem comfortable almost everywhere except in
the clouds of dense gas where stars are born.
"The carriers are readily
formed but not readily destroyed in a wide range of different environments,"
says Cordiner. "It's remarkable how tenacious these molecules really
are."
In short, carriers are thought to be made of carbon, Cami says,
"because it's a lot easier to build strong and stable molecules from carbon
atoms than from other elements, such as silicon or sulfur. Using those elements
rather than carbon would be like building a house from a bucket of sand while
there's a huge pile of bricks at the construction site."
The top three
carrier candidates are: chain-like molecules, like the one now tentatively
associated with a pattern of DIBs; PAHs, which often come up in studies of how
planets formed; and compounds related to fullerenes, the soccer-ball-shaped
molecules also known as buckyballs.
"This list covers most types of
carbon molecules," notes Cami. "Chains are essentially the one-dimensional
carbon molecules, PAHs are the two-dimensional ones, and fullerene compounds are
the three-dimensional ones."
Present and accounted for
In
spite of the challenges of looking for DIBs in other galaxies, it's worth the
effort to astronomers because they need to see what DIBs look like under
different conditions.
Granted, conditions are not uniform everywhere
within a galaxy. Some stars have planets near them; others don't. Between the
stars, in the vast tracts of interstellar medium, the relative amounts of gas
and dust floating around can be different from one region to the next. And the
exact mixture of chemicals can vary a little from place to place.
"But
being on Earth and looking at another object in the Milky Way is like being in
the crowd at Times Square in New York City on New Year's Eve and trying to find
your friend," explains Nuth. "It's much easier to spot the person if you are on
a balcony rather than standing in the crowd yourself." Likewise, it's much
easier to get a clear overview of a galaxy when you are outside of it.
In
some respects, Andromeda and the Triangulum are similar to the Milky Way. All
three are spiral galaxies that belong to a collection of more than 30 nearby
galaxies called the Local Group. The Milky Way is the largest member of this
group. Andromeda is the second-largest, and the Triangulum is third.
Like
the Milky Way, Andromeda and the Triangulum are thought to be good places to
synthesize large organic molecules, which is what DIBs carriers are thought to
be. And yet, says Cordiner, "nobody knew until now whether DIBs actually existed
in either galaxy."
The team found that, indeed, DIBs do exist in both
places, and they are strong, which implies there are many carriers.
In
the Milky Way, when researchers find strong DIBs, they tend to find a lot of
dust, too. This makes sense, because whenever there's more raw material
available to make DIBs carriers, there's also more available to make dust. The
team found the same situation in Andromeda, Cordiner says.
Of greater
interest in Andromeda was whether the strength of the DIBs was related to the
amount of PAHs, which are high on the list of candidates for carriers. The
researchers knew going into the study that PAHs are plentiful in Andromeda, as
they are in the Milky Way.
"The details of the PAH population seem to be
somewhat different in Andromeda, though," says Cami. "This makes it interesting
to try and find out exactly what is different."
But after checking to see
if the PAH levels were related to DIBs strength, "we didn't find any correlation
between the two," Cordiner says. That finding doesn't rule out a connection, but
it might shift more attention to chains of carbon atoms or to fullerene
compounds.
The carriers are not pure, isolated fullerenes, says Cami, who
led the team that first detected fullerenes in space. More likely, "atoms or
molecules are either locked up in fullerene cages or attached to the outside
surface, " he explains. "This might even hold for some of the other proposed
molecules. For example, you could think of carbon chains dangling from other
molecules or even from dust grains."
The more things change . .
.
One big difference between the Milky Way and Andromeda is the
number of massive young stars. The Milky Way has more than Andromeda. Because
those young stars generate a lot of UV radiation, the Milky Way's interstellar
medium has higher levels of this radiation than Andromeda's does.
More
radiation means a harsher environment, so organic molecules should survive
better in an environment with less radiation. In that sense, Andromeda should be
more favorable for the carriers of DIBs and, in theory, should be able to boast
more of them. But Cordiner and his colleagues found that the DIBs in Andromeda
were only slightly stronger than those in the Milky Way, implying that Andromeda
can only claim slightly more carriers.
The observations in the Triangulum
add even more intrigue. There, the researchers found strong DIBs even though
this galaxy differs in its metallicity, which is a measure of the availability
of ingredients for making stars and planets.
The consistency from galaxy
to galaxy is surprising, given how much the conditions are thought to vary among
them. "But there are no detailed studies of Andromeda to tell us everything we
want to know about conditions there," says Cordiner. "And even less is known
about the Triangulum."
As is usually the case in cutting-edge astronomy,
some assumptions had to be made, and a lot depends on how well those assumptions
hold up as more information becomes available.
Meanwhile, researchers
will try to learn everything they can about DIBs near and far and the organic
molecules they represent. "If we're going to understand fully how interstellar
chemistry works—how stars and planets form," says Cordiner, "then we need a full
understanding of the ingredients they use."
