In the last episode, I talked about stars that are orbiting one another. When it's
two stars it's called a binary. Three stars would be a trinary system, and so on. But
what happens if you have ten stars? A thousand? A MILLION?
What do you call it when stars CLUSTER together?
It's likely that some stars are born individually, but astronomers think that most stars are born in
groups called clusters, sometimes hundreds and sometimes HUNDREDS OF THOUSANDS at a time.
There are two kinds of clusters. Open, or galactic clusters, and globular clusters.
Open clusters are loosely bound collections of dozens or thousands of stars, usually in
an irregular shape. Some are big enough and close enough to us that they can be seen by
the naked eye; faint fuzzy patches in the sky. Galileo was the first to discover, or
at least record, the fact that they were actually composed of many stars so close together our
unaided eyes couldn't resolve them.
As we'll see in next week's episode, clusters are formed from gigantic clouds of gas and
dust. Depending on local conditions (like how massive they are) these clouds can form
dozens, hundreds, or thousands of dense clumps, which then contract to form individual stars.
These stars can be bound together by their mutual gravity, forming an open cluster. Unlike
the solar system, where the Sun dominates and provides a singular, central source of
gravity holding the planets under its sway, in a cluster ALL the stars contribute to the
overall gravity, so there's a more general gravitational schmear. The stars all orbit
the cluster's center of mass, even though there may not be anything at the very center.
Not only that, but the stars don't all orbit in a flat plane, like our planets do. Instead, their orbits
are tilted in all different directions, more like the way long period comets are scattered around the Sun.
Typically, an open cluster is a couple of dozen light years across, with stars much
closer together than they are in interstellar space; the nearest known star to the Sun is
over 4 light years away, while stars in an open cluster are typically a fraction of a light year apart.
Some clusters are very young — well, in an astronomical sense. They're a few million
years old. Others are far, far older, billions of years in age.
How do we know? By looking at the stars themselves. Remember, hot, blue, massive stars don't
live long before exploding. If a cluster has those kinds of stars it must be pretty youthful.
If all it has are much lower mass red dwarfs, it must be be much older,
all the more massive stars having died off.
In fact, clusters are pretty useful this way. If you assume all the stars in them were born
at the same time — a reasonable starting guess — then the age can be found by looking
at the most massive stars still on the main sequence, still fusing hydrogen into helium
like the Sun is. The most massive stars can be identified by their spectra, which gives
us their mass, and then that can be used to get the cluster's age.
You might expect the distribution of cluster ages to be all over the place, with some young,
some old, and some middle-aged. But in fact, most clusters are young, and very few are
older than roughly 50 million years. That's because they evaporate.
All the stars in the cluster interact with each other via gravity. That means they constantly
tug on one another, changing each others' orbits. You may remember from our episode
about gravity, that the kind of orbit an object has depends on the amount of energy it has.
Give it more energy and the orbit gets bigger. Give it enough energy and it will achieve
escape velocity and fly away.
In clusters the stars are always passing by each other and exchanging energy via their
gravity. If a low mass star swings past a higher mass star, it can get a relatively
big kick to its energy, and get flung into a much higher orbit in the cluster, while
the high mass star loses energy, dropping it down toward the center.
Over time, these interactions tend to flick the lower mass stars out of the cluster completely,
and the cluster loses stars. It starts with the lowest mass stars, but as they leave even
higher mass stars can be lost this way. Eventually only the most massive stars are left, and
those tend to blow up. Even then, the remaining neutron stars and black holes interact and
fling each other way. This process is aided by collisions with gas clouds and the tidal
forces of the collected stars in the galaxy itself. Given enough time, the cluster just…
disappears. The individual stars are left to orbit the galaxy on their own.
About a thousand open clusters are known. But their days are numbered. Eventually, over
millions of years, they'll go away, their stars scattered across tens of thousands of
light years, merging with the population of other stars in space. So, better observe them while you can.
One of the most famous and beautiful open clusters in the sky is the Pleiades, about
500 light years from Earth. They appear as a small, tightly-packed collection of six
or seven stars to the eye, and a lot of people call them the Seven Sisters.
Through binoculars several dozen stars can be seen. Most of them look blue, but that's
what we in the science business call a selection effect or selection bias: The blue stars are
the brightest, so we see them more easily. Through a telescope redder stars are apparent.
Long exposures of the Pleiades reveal a surprise: The stars are embedded in a dust cloud, which
glows blue from reflected and scattered starlight. When I was younger it was thought that this
was the leftover stuff from which the stars formed. But now we know it's a coincidence;
by sheer happenstance the cluster is colliding with an unrelated cloud of dust -- it's
like driving a car through a dust cloud thrown up by a truck that went past you earlier.
By another coincidence, the Pleiades are located in the sky next to the Hyades, the only other
cluster with stars resolvable by the naked eye. The Hyades are much closer, and appear
bigger; in fact they form the distinctive V-shape of the horns of Taurus, the Bull!
As someone who enjoys taking out a telescope and observing the sky, I'm a fan of open
clusters, and a few are favorite targets whenever I'm outside; I love looking at the Pleiades
with binoculars, and M35 at the foot of Gemini is another must-see for me in the winter through
my telescope.
But as much fun as they are to find, and as beautiful as they are to see, they can't
hold a candle to globular clusters.
These are clusters of not thousands, but HUNDREDS of thousands of stars! They form a roughly
spherical shape, hence the term globular, and generally have a well-defined core with
stars scattered around them in a halo that fades away with distance. Most globulars are
bigger than open clusters, with diameters perhaps a hundred light years across, though
size is a bit hard to measure, since they don't really have an edge.
Like open clusters, the stars in them orbit every which way, like bees around a beehive.
Unlike open clusters, though, globulars are old. VERY old; most are over ten billion years
old! We think they were among the first objects to form after the Universe itself did.
We know this because in most globulars, the MOST massive stars are LESS massive than the
Sun. They've been around so long that even stars like the Sun have had enough time to
become red giants and die, and that takes a long, LONG time.
The stars in globular clusters tend to have less heavy elements in them too, which you
expect if they're old. Massive stars explode and scatter their heavy elements into the
Universe, and that takes time. It took billions of years for stars like the Sun to form, the
ones with more heavy elements in them. Old stars formed before the Universe was seeded with
those elements, so they have more lighter elements in them than later-generation stars like the Sun.
Despite being larger than open clusters, globulars have more stars and are denser, which is one
reason they live longer than open clusters. Another is that they tend to spend most of
their lives outside the galaxy on long, looping orbits, and there's nothing out there to
interfere with their solitary existence.
Globulars are great laboratories for stellar astrophysicists. All the stars in them are
born at the same time, and so they're the same age. They're also the same distance
from Earth so if you see one star in a globular that's twice as bright as another, it really
IS twice as luminous. That's handy if you're comparing stars for other characteristics.
Because globulars are so old, they contain a lot of dead stars. We see quite a few white
dwarfs, as well as neutron stars and black holes in them — if they have stellar companions,
they strip off their material, which falls in and emits X-rays. What normal stars are
left are low mass red stars, so globulars tend to look red.
Weirdly, there ARE some blue stars in globulars, called blue stragglers, and they were mystery
at first, since they shouldn't be there in such old objects. But astronomers figured
out they're actually stars that have physically collided and merged to form a single, higher
mass star. Such collisions are extremely rare in space, but the stars are so tightly packed
in globulars that collisions are more common.
We know of about 150 globular clusters orbiting the Milky Way galaxy — our own local collection
of stars that we'll dive into in more detail in an episode very soon — but other galaxies
have more, many hundreds or even thousands.
Globulars are among my very favorite objects to observe with a small telescope; they are
bright, compact, and their fuzziness due to so many stars packed so closely together gives
them an illusion of activity, again like bees swarming a hive. They are incredibly beautiful.
And that's the view from tens of thousands of light years away. Imagine what the sky
would look like from a planet orbiting a star inside the cluster! The sky would be filled
with stars, some so close and luminous there could be dozens brighter than Venus appears
in our sky. At night you might be able to read by starlight!
Sadly, though, this fantastic sight is probably more science fiction than science. Because
globular stars lack heavy metals, it's unlikely they would've formed planets like Earth.
And the stars are so closely packed that nearby encounters might eject any planets that did form.
Such a scene would be amazing, but unfortunately it's probably one that exists only in our imagination.
Today you learned that open clusters contain hundreds or thousands of stars held together
by gravity. They're young, and evaporate over time, their stars let loose to roam space
freely. Globular clusters are larger, have hundreds of thousands of stars, and are more
spherical. They're very old, a significant fraction of the age of the Universe itself,
and that means their stars have less heavy elements in them, are redder, and probably
don't have planets (though we're not really sure).
Crash Course Astronomy is produced in association with PBS Digital Studios. Head over to their
YouTube channel to catch even more awesome videos. This episode was written by me, Phil
Plait. The script was edited by Blake de Pastino and our consultant is Dr. Michelle Thaller.
It was directed by Nicholas Jenkins, edited by Nicole Sweeney, the sound designer is Michael
Aranda, and the graphics team is Thought Café.