Tip:
Highlight text to annotate it
X
So how do we know that there is a core,
and that the core is made up of a liquid outer core
and a solid inner core?
And the answer there comes from the same technique
that we saw Mohorovicic use in 1909 to essentially see
the behavior, or when you measure the seismic waves,
or whether you can even measure the seismic waves,
the different distances from an earthquake.
So if there's an earthquake right here.
We're calling that zero degrees.
Let's remember a couple of things here.
Let's remember that P-waves can travel through anything.
They can travel through solid or liquid or air for that matter.
So they can travel through anything.
But S-waves, S for secondary, these are the transverse waves,
these can only travel through solids.
So it turns out that if an earthquake happens
at zero degrees, and you had seismograph stations
all over the world, and these are extremely sensitive
in order to be able to measure earthquakes that are happening
thousands of kilometers away, it turns out
that there's something called an S shadow, an S-wave shadow.
If these are S-waves you can measure them here.
You can measure them here.
They can go all the way over here.
They can go over here.
They can go over there.
You can measure them over here.
So you could measure them at all of these points,
but then all of a sudden at 105 degrees,
and so we're measuring zero degrees here
and we're going outwards like that,
all of a sudden at 105 degrees and further
you stop measuring S-waves.
For some reason you would think that some of the S-waves
would get over here, maybe they would be a little bit weaker,
but they would be able to get all the way over here.
But they just abruptly stop.
No more S-waves.
So in this whole area right over here you get no S-waves.
And obviously I could flip this picture over
and you would see a symmetric thing
on the other side of the globe that all of this area over here
you also would not see S-waves.
You'd only see them from 105 degrees in this direction
and 105 degrees in that direction.
And the only reasonable explanation that we can give is
that there must be some material that an S-wave cannot travel
through that it would have to travel through to get to these
points beyond 105 degrees.
And we know that S-waves only travel in solids.
So the assumption there is that at some point beyond 105
degrees it's hitting liquid.
So that's what tells us that this right here
is probably a liquid.
It's hitting some layer that is liquid.
So that tells us that there's a core,
and at least the outer part of that core is liquid,
enough to stop S-waves.
So the S-waves, because it only travels in solids
it leads to this S-wave shadow.
And this tells us that we have a core.
And that core, at least the outer part, is liquid.
We don't know yet whether the inner part is liquid or solid.
Now, the next point of evidence is
how do we know that there's an inner core?
And we can use P-waves for that.
A P-wave can travel through anything,
but remember, in general for the same type of material
if you get denser material it's going to move faster,
so it's going to refract outwards
like we've seen over here.
But if it goes into a liquid, in general, sound waves,
or I should say P-waves, seismic waves move slower in liquids.
And so the refraction patterns we
get when we do measure from seismograph stations
around the world is that it looks like the P-waves are kind
of doing what you would expect in the mantle,
but then they're getting refracted
as if they're going to a slower medium
as they go through the outer core.
And we see that right over here.
And then they get refracted again
to get to some point on the other side.
Now, that is just what you would expect if it was all liquid,
but if you go to stations that are even further out
it looks like, if you just look at the refraction patterns,
and you can now model this with fancy computers
and get all the data points, but you could say,
well, the only way that reality can fit the data that we
get based on when things reach here
is if the P-waves are being first refracted
through the outer core, but then they're refracted in a way
that they're going through denser material, significantly
denser material than the inner core.
And then they're just continuing to refract
the way you would expect.
So it's really the refraction pattern of the P-waves.
And frankly, the fact that there's
this what you call a P-wave shadow.
The P-wave shadow by itself, all that
tells you is that kind of roughly crazy things
are happening someplace in the core.
But the real way to know that we have an inner core that's
solid, as opposed to the whole thing being liquid,
is that the P-waves is the pattern
of when and how the P-waves reach
essentially the other side of the globe.
And then you can kind of, based on modeling
how waves would travel through different densities
and different types of mediums, you could say,
well, there's got to be an inner core right over here.
And obviously, it's a lot more math than I'm going into.
But if you do the math based on the shadow,
and you know the speed of the material,
and all of that type of thing, then you
can figure out the depth at which these transitions occur.
We know that we have a transition from mantle
to outer core here.
And then a transition from outer core to core there.
So hopefully that satiates your questions
about how do we know what the composition of the earth
is without ever having to dig down there,
because we've never even gotten below our crust.