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When you picture a spaceship,
you probably think of something like this,
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or this, or maybe this.
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What do they all have in common?
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Among other things, they're huge
because they have to carry people, fuel,
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and all sorts of supplies,
scientific instruments,
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and, in rare cases, planet-killing lasers.
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But the next real-world generation
of spacecraft may be much, much smaller.
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We're talking fit-inside-your-pocket tiny.
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Imagine sending a swarm of these
microspacecraft out into the galaxy.
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They could explore
distant stars and planets
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by carrying sophisticated
electronic sensors
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that would measure everything
from temperature to cosmic rays.
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You could deploy thousands of them
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for the cost of a single
space shuttle mission,
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exponentially increasing
the amount of data
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we could collect about the universe.
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And they're individually expendable,
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meaning that we could send them
into environments
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that are too risky
for a billion dollar rocket or probe.
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Several hundred small spacecraft
are already orbiting the Earth,
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taking pictures of outer space,
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and collecting data on things,
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like the behavior of bacteria
in the Earth's atmosphere
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and magnetic signals that could help
predict earthquakes.
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But imagine how much more we could learn
if they could fly beyond Earth's orbit.
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That's exactly what organizations,
like NASA, want to do:
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send microspacecraft
to scout habitable planets
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and describe astronomical phenomena
we can't study from Earth.
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But something so small can't carry
a large engine or tons of fuel,
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so how would such a vessel propel itself?
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For microspacecraft, it turns out,
you need micropropulsion.
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On really small scales,
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some of the familiar
rules of physics don't apply,
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in particular, everyday
Newtonian mechanics break down,
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and forces that are normally negligible
become powerful.
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Those forces include surface tension
and capillary action,
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the phenomena
that govern other small things.
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Micropropulsion systems can harness
these forces to power spacecraft.
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One example of how this might work
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is called microfluidic
electrospray propulsion.
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It's a type of ion thruster,
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which means that it shoots out
charged particles to generate momentum.
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One model being developed at NASA's
jet propulsion laboratory
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is only a couple centimeters
on each side.
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Here's how it works.
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That postage-stamp sized metal plate
is studded with a hundred skinny needles
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and coated with a metal
that has a low melting point, like indium.
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A metal grid sits above the needles,
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and an electric field is set up
between the grid and the plate.
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When the plate is heated,
the indium melts
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and capillary action draws
the liquid metal up the needles.
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The electric field tugs
the molten metal upwards,
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while surface tension pulls it back,
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causing the indium to deform into a cone.
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The small radius of the tips
of the needles
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makes it possible for the electric field
to overcome the surface tension,
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and when that happens,
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positively charged ions shoot off at
speeds of tens of kilometers per second.
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That stream of ions propels the spacecraft
in the opposite direction,
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thanks to Newton's third law.
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And while each ion
is an extremely small particle,
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the combined force of so many of them
pushing away from the craft
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is enough to generate
significant acceleration.
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And unlike the exhaust
that pours out of a rocket engine,
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this stream is much smaller
and far more fuel efficient,
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which makes it better suited
for long deep-space missions.
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These micropropulsion systems
haven't been fully tested yet,
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but some scientists think that they
will provide enough thrust
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to break small craft out of Earth's orbit.
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In fact, they're predicting that thousands
of microspacecraft
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will be launched in the next ten years
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to gather data that today
we can only dream about.
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And that is micro-rocket science.
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