A high-velocity star leaving a galaxy and headed into intergalactic space. Image credit: NASA. |
Although the stars in our galaxy will live for billions of years,
every once in a while, a catastrophe could happen that knocked one out
of its stable orbit around our galaxy. Would it be possible for one to
not only be perturbed, but to be ejected entirely? And if it were, is
there any chance that you could still hang onto your planets, perhaps
resulting in a habitable, intergalactic world, where your “Sun” (and
perhaps some other planets) comprises the only bright light you’ll
see?
"Is it possible for a star to escape the gravitational pull of its galaxy? If so, could it do so with orbiting planets? If so, if you were on a planet and gazing at the night sky, would you see constellations made up of galaxies?"
The first time you look up at the stars in our night sky, it may come as
a surprise to realize that every single one is located in our own Milky
Way galaxy. Not only that, but the overwhelming majority of the ones we
can see are within a few hundred light years of Earth: peanuts on a
galactic scale. Like our Sun, they revolve around our galaxy’s center at
around 220 km/s, with most of them having additional motions of ±20
km/s on top of that, which is why the stars’ relative positions change
over time. Practically every one isn’t just a single fiery ball of
fusion and light, either, but likely has its own solar system, complete
with planets and sometimes other stars as well. For the most part, these
stars simply move through the galaxy in a nice, stable orbit, thanks to
the fact that the Milky Way’s gravity is quite predictable and that
other stars passing close to it are relatively rare occurrences.
But stars live a long time, and although the distances between them are
very great, close approaches do happen with some regularity. While
speeds of ~220 km/s are enough to keep us in a nearly circular orbit
around the galactic center, another few hundred km/s should be enough to
get us out of the galaxy entirely. Based on data from the RAdial Velocity Experiment (RAVE) survey,
where data from nearly 100 high-velocity stars was gathered and
analyzed, we were able to determine that the total mass of the Milky way
is around 1.6 trillion solar masses, meaning the escape velocity at our
distance is somewhere between 500-550 km/s. Another boost of 300 km/s
in the right direction or so, and intergalactic space becomes our
destination.
Close gravitational interactions between stars aren’t so incredibly
rare, either. Once every million years or so, a star comes within the
vicinity of the Sun’s Oort cloud, and probably about five times in our
history, we’ve had a star approach at the distance of the Kuiper belt.
There are even some stars in our galaxy that are moving so fast that we
know they received a recent gravitational “boost” from some mass (or
mass concentration), like Mira, as evidenced by a “tail” left as they move through interstellar space.
The fast-moving star Mira, with its tail (above), in ultraviolet (top) and visible (bottom) light. Image credit: NASA/JPL-Caltech/POSS-II/DSS/C. Martin (Caltech)/M. Seibert(OCIW). |
Mira, moving at “only” an extra 63 km/s, won’t leave our galaxy anytime
soon, but there’s an important fact to note about it: Mira has a white
dwarf companion, meaning that large gravitational “kicks” often aren’t
enough to unbind a solar system! We can, however, look to the fastest
star in the Milky Way galaxy – US 708 — to find one that will escape. At a speed of 1200 km/s, it may have gotten its kick from a supernova (perhaps even a rare “double detonation” supernova), and is headed out of the Milky Way.
There ought to be significant numbers of stars littering intergalactic
space, as the Universe has had more than ten billion years to eject
stars from its galaxies. Moreover, regions where stars form — open and
globular clusters — are incredibly dense, with large numbers of stars in
very small volumes, providing many opportunities for the gravitational
slingshot effect. There’s an effect that arises that’s so well studied
and so well simulated that we have a special name for it: violent
relaxation. When many masses of different magnitudes are bound together,
the lightest masses tend to get kicked out at breakneck speed, while
the remaining masses wind up more tightly bound. This explains why some
of the oldest globular clusters are so heavily concentrated towards
their cores.
The globular cluster Messier 75, showing a huge central concentration, is over 13 billion years old. Image credit: HST / Fabian RRRR, with data from the Hubble Legacy Archive. |
While an interaction that happens too close to a planet could
eject that as well, simulations indicate that’s a rarity, and that most
planets should remain intact. While there are likely under a million
stars that have been ejected from our Milky Way so far, our Universe is
still pretty young. By time many quadrillions of years have passed, that
number will rise to most stars that ever existed in the Milky
Way being kicked out, including (probably) whatever’s left of our Sun.
The first intergalactic stars were discovered in the Virgo Cluster in
1997, proving that this is a phenomenon that’s been at play for a long
time.
Photo of the Center of the Virgo Cluster of Galaxies with names and magnitudes. Image credit: Bernd Gährken. |
Either by gravitational or supernova-powered kicks, stars get kicked out
of galaxies all the time. When they do, they wind up in intergalactic
space, with night skies that are littered only with distant galaxies,
which might give you a view — at any moment — like a still shot from the
movie
What you’d see wouldn’t look like constellations, but rather would trace
out the large-scale structure of the Universe. And perhaps you’d
wonder, if you didn’t know better, why your Sun was the only
star-like thing in the night sky, and how you got so unlucky that all
you’d see would be these distant smudges. Were they made up of billions
of stars like yours, while you were just incredibly unlucky to be so
alone? Or would you be the lucky one, to have a view of the entire
Universe without a galaxy to stand in your way? It all depends on your
perspective!
by Ethan Siegel
by Ethan Siegel
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