(J. Louie)
The earth is divided into four main layers: the inner core,
outer core, mantle, and crust.
The core is composed mostly of iron (Fe) and is so hot that the outer core is
molten, with about 10% sulphur (S).
The inner core is under such extreme pressure that it remains solid.
Most of the Earth's mass is in the mantle, which is composed of iron
(Fe), magnesium (Mg), aluminum (Al), silicon (Si), and oxygen (O) silicate
compounds.
At over 1000 degrees C, the mantle is solid but can deform slowly in a
plastic manner.
The crust is much thinner than any of the other layers, and is composed of the
least dense calcium (Ca) and sodium (Na) aluminum-silicate minerals.
Being relatively cold, the crust is rocky and brittle, so it can fracture
in earthquakes.
In addition, the two types of seismic wave behave differently, depending on the material. Compressional P waves will travel and refract through both fluid and solid materials. Shear S waves, however, cannot travel through fluids like air or water. Fluids cannot support the side-to-side particle motion that makes S waves.
(J. Louie)
Seismologists noticed that records from an earthquake made around the
world changed radically once the event was more than a certain
distance away, about 105 degrees in terms of the angle between the earthquake
and the seismograph as measured at the center of the earth.
After 105 degrees the direct P- and S- waves disappeared almost completely, but slow surface waves and waves taking other paths would arrive from over the horizon.
The area beyond 105 degrees distance forms a shadow zone.
At larger distances, some P waves that travel through the liquid core (path K on the figure above) would arrive, but still no S waves.
The Earth has to have a molten, fluid core to explain the lack of S waves
in the shadow zone, and the bending of P waves to form their shadow zone.
(J. Louie)
You can get a rough estimate of the size of the Earth's core by
simply assuming that the last S wave, before the shadow zone starts at
105 degrees, travels in a straight line. Knowing that the Earth has a
radius of about 6370 km, you have a right triangle where the cosine of
half of 105 degrees equals the radius of the core divided by the radius of
the earth.
The fact that the Earth has a magnetic field is an independent piece of evidence for a molten, liquid core. A compass magnet aligns with the magnetic field anywhere on the Earth. The earth cannot be a large permanent magnet, since magnetic minerals lose their magnetism when they are hotter than about 500 degrees C. Almost all of the earth is hotter, and the only other way to make a magnetic field is with a circulating electric current. Circulation and convection of electrically conductive molten iron in the Earth's outer core produces the magnetic field. To make the magnetic field, the convection must be relatively rapid (much faster than it is in the plastic mantle), so the core must be fluid. Much of the energy to drive this convection comes from growth of the solid inner core, with the release of energy as the iron changes from solid to liquid.
(J. Louie, after a class chalkboard drawing by
David Stevenson)
Because the Earth's magnetic field arises in the unstable patterns of fluid
flow in the core, it changes direction at irregular intervals.
In recent geologic history it may have switched direction about every 200,000
years.
Any kind of geologic deposit (e.g.: lava flows, layered muds) put down over
time will thus have different layers magnetized in opposing directions,
recording the magnetic field direction as it was when the layer solidified.
Geophysicists can measure the changes in direction to make a
magnetostratigraphy for the deposit.
At oceanic spreading centers new ocean floor is being created constantly
and slowly moved away from the rift.
The farther the rock is from the rift, the older it is, and it will also show the
magnetic reversals like a tape recording.
(from Acton and Petronotis,
EOS, 1994;
Amer. Geophys. Union)
This map of the Pacific Plate at various stages of geologic history
could be constructed from the tape recording.
Such maps show how the tectonic plates have
re-arranged themselves over the last 200 million years.
(original image
from the Harvard Univ.
Seismology Lab;
used by permission)
In this view from the southwest the red blobs are warmer
plumes of less dense material, rising principally into the ocean-ridge
spreading centers.
A huge plume seems to be feeding spreading at the East Pacific Rise directly
from the core.
Most of the heat being released from the earth's interior emerges at the
fast-spreading East Pacific Rise.
(J. Louie)
The part of the mantle near the crust, about 50-100 km down,
is especially soft and plastic, and is called the asthenosphere.
The mantle and crust above are cool enough to be tough and elastic, and
are known as the lithosphere.
A heavy load on the crust, like an ice cap, large glacial lake, or mountain range, can
bend the lithosphere down into the asthenosphere, which can flow out of
the way.
The load will sink until it is supported by buoyancy.
If an ice cap melts or lake dries up due to climatic changes, or a mountain range erodes
away, the lithosphere will buoyantly rise back up over thousands of years.
This is the process of isostatic rebound.
Seismic reflection sections can show blocks of the crust in great detail.
Individual layers can be studied for their potential to hold oil, gas, or water;
to conduct contaminants from a dump site; or to describe their geologic
origin and history.
(from Soc. of Explor.
Geophysicists, The Leading Edge, v. 11, no. 11, p. 13;
used by permission)
This study of one layer maps out an ancient network of sandy stream channels,
much like the modern channels of the Laramie River, right. Such buried
channels can yield oil or gas easily if seismic reflection work can pinpoint their
locations.
(from Soc. of Explor.
Geophysicists, The Leading Edge, v. 12, no. 6, p. 683;
v. 11, no. 8, p. 13; used by permission)
Development geophysicists can build detailed models of complex structures
having many different formations deformed by all types of faults and folds.
With these details they can plan the extraction of oil, gas, coal, or other
minerals. They can also predict how ground water may flow through
an area, and find the most efficient strategies to clean up contamination.
(from Soc. of Explor.
Geophysicists, The Leading Edge, v. 10, no. 8, p. 15;
used by permission)
Geophysicists can also make maps of other physical properties that rocks show over an area. Gravitational pull, magnetic field strength, electrical conductivity, radioactivity, and spectral reflectance are all properties that may be used to detect particular rock formations of economic or geologic interest, even if they are buried below the surface.
(from Soc. of Explor.
Geophysicists, The Leading Edge, v. 9, no. 9, p. 41;
used by permission)
The maps above are derived from maps of magnetic field strength in a part of Nevada.
Computerized artificial illumination from the right direction reveals a subtle
lineament in the image. A buried, slightly magnetized dike
could contain gold ores.
(from Soc. of Explor.
Geophysicists, The Leading Edge, v. 9, no. 9, p. 39;
used by permission)
The image above is the output of a ground-probing radar, which is
very good at locating buried pipes, cavities, fractures, and metallic objects.
Here it reveals the detailed structure of a soil layer only 20 m thick, showing
channels likely to collect contaminated ground water.
J. Louie, 10 Oct. 1996
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