Geoscience Reference
In-Depth Information
11
The solid Earth
Before discussing the formation of the major geological units of the solid Earth, we should
review the internal structure of our planet as described by seismic wave studies (
Fig. 11.1
).
The most important discontinuities observed by seismologists are:
•
The base of the crust (called the Mohorovicic discontinuity or Moho), 40 km below the
continents, but only 5-7 km beneath the oceans.
•
The base of the lithosphere, on average 80 km below the oceans, and deeper still beneath
the continents. Rather than a discontinuity, this is a rather diffuse transition. This is
the lower boundary of the rigid tectonic plates. The softer part of the upper mantle
underneath the lithosphere is called the asthenosphere.
•
The 410 km discontinuity corresponding to a change in olivine structure (spinel or
ringwoodite phase).
•
The 660 km discontinuity corresponding to the transformation of all minerals into
perovskite and minor Fe-Mg oxide (magnesio-wüstite). This is the base of the upper
mantle.
•
The mantle-core boundary at about 2900 km. Above this boundary is a seismically
abnormal layer some 200 km thick, known as the
D
layer.
•
The outer core-inner core boundary at about 5150 km. The core is composed mostly
of metallic iron and nickel. The motion of the fluid outer core generates the Earth's
magnetic field.
Plate tectonics is a powerful theory that unifies the geological expression of crustal
lithospheric plates that may or may not carry continents. These plates are about 80 km
