MICHELLE THALLER: I'm an astrophysicist and
one of the things that I have been really
impressed with with the International Space
Station, some of the most amazing and innovating
and strange experiments today are actually
located on the space station.
It's, of course, a wonderful platform to look
at a lot of stuff because you're up above
the atmosphere, you're up in space and you
can both look out into space and you can also
look back down at our home planet the Earth.
One of the things that makes it a challenge
to actually use it as, for example, an observatory
with telescopes is that the space station
swings around a lot so you have to be able
to actually stabilize the image and what you're
looking at, especially if you're working on
the space station.
But to me certainly one of the most amazing
discoveries of the last year has come out
of the space station experiment called NICER,
that's the acronym.
It stands for the Neutron star Interior Composition
Explorer so NICER.
And NICER it's actually a camera that looks
at x-ray light.
So, this is very, very high energy light and
luckily for us this light does not get through
the atmosphere.
There are x-rays coming from space all the
time and they would be very harmful to us
but they're absorbed by the air in the Earth's
atmosphere.
Of course that means if you want to study
x-rays coming from space you need to get up
above the atmosphere and the space station
is.
Now, NICER was specifically designed to look
at a very interesting type of dead star called
a neutron star.
And a neutron star is the remnants when a
very massive star, a star that might have
been 10, 20, 50 times the mass of the sun
violently dies and explodes.
And incredibly the core of the star is usually
still intact after that because the core became
so compressed in that explosion that it holds
together as a giant ball of atoms basically.
Neutron stars are only about ten miles across.
They have the density of one big atomic nucleus
and that means that if you had a teaspoon
full of this material, this neutronium, that
teaspoonful would have about as much mass
as Mount Everest.
So, a ten mile ball every little bit of it
is that dense and not only that these things
spin hundreds of times a second.
They are wonderful.
They are real monsters.
The gravity around them is so intense, it's
not a black hole but it's sort of natures
next best thing.
The gravity is so intense that light is actually
bent around these objects.
And one of the most amazing things that we
did with NICER recently is we used data coming
in from x-rays from these hot dense little
balls to actually map the surface and see
where parts were hotter than others.
And that was very challenging to do because
when you actually took an image, and this
wasn't a simple image it was constructed out
of many different observations, but what you're
actually doing is you're not only seeing the
front of that object but you're seeing the
back of the object too because light is bending
around the object.
Gravity is so strong it actually warps light
around so that you see the front and the back
of the object at once.
And so, to make this map we had to actually
sort of deconvolve which parts were from the
front of this neutron star and which parts
were from the back.
Now, another thing that is just kind of wonderful
is that these things spin around as I said
hundreds of times a second.
And as they do they emit burst of radiation
every time they make a spin.
And that's a very, very accurate clock, they're
actually more accurate than most clocks here
on Earth.
And what we're doing now is we're trying to
use those bursts of radiation coming hundreds
of times a second to create a timing device
all around the Earth.
And what that will be is something like a
system of GPS satellites, global positioning
satellite.
So, all of those tiny little signals each
one is a little different, each neutron star
spins at a slightly different rate and you
can triangulate exactly where you are based
on these blips that are coming at you from
the neutron stars.
And what that means is that we'll have a GPS
system we can use anywhere in the galaxy.
So, even our deep space probes you get far
away from earth like say you want to go out
to Saturn, we don't have any GPS satellites
out by Saturn; it's hard to know exactly where
you are and we still use the positions of
stars around the spacecraft to do that.
But what if you had a GPS system that will
never go out, it will never go down, it will
stay accurate for many, many centuries if
not millennia and it's not based on anything
technological, anything human driven it's
based on rotating dead stars in the sky?
Conceivably we could go to any of these planets
that we're discovering, more than 4000 planets
now around other stars, and using the same
system we would know exactly where we are.
So, you might not think about it but right
now the space station at this moment is taking
data from hundreds, if not thousands, of these
spinning dead stars and we're using it to
find our place in the galaxy.
