In the classical and simplified sch

In the classical and simplified schema of the magnetosphere, the charged particles composing the solar wind start to interact with the lines of the geomagnetic field on the dayside direction producing a shock wave, known-as a bow shock for its shape, which could be considered as the border of the circum terrestrial region. Most of the particles deflected by the bow shock flow along a transition region called the magnetic sheath while a fraction of the particles penetrate into the so-called magnetosphere, the region bounded by the magnetopause. Within this region
the charged particles are influenced by the Earth’s geomagnetic and electric fields.
There is another region below the lower portion of the magnetosphere called
the plasmasphere, which is shaped like a torus around the Earth. The plasmasphere
is composed of relatively cool plasma of hydrogen ions and can be considered the
upper or outermost portion of the ionosphere, lying above 1,000 km in altitude.
This transition region is very influential during measurements of total electron
content by satellites, and in all issues affecting Earth-space radio propagation.
The ogive shaped geomagnetic tail extends for over 200 terrestrial radii. The
plasma in this portion of the magnetosphere has a different composition: there
is an external plasma mantle of very low density and an internal central plasma
sheet. The complex behaviour of the particles in the distant regions of the tail are
not relevant to the present discussion. It is important to note the two polar cusps
at the points where the magnetosphere is in contact with the Earth. Through these
two zones there is precipitation of charged particles from the solar wind into the
upper atmosphere of the so-called auroral regions.
Finally, the presence of two radiation layers trapped by the fields of the magnetosphere
and discovered during space missions is also very important. These are
known as the Van Allen Belts. The first layer of radiation is found along the magnetic
equator at a distance between 1,000 km to 3 Earth radii from the surface of
the planet and is composed of protons from the solar wind and from the lower
ionosphere. The second layer is at a distance of between 4 and 6 Earth radii and is
composed mainly of electrons, again originating from the solar wind. These particles
are subject to a rotary movement around the lines of the geomagnetic field
as shown in Fig. 2.14, oscillating between North and South. In addition to this
oscillation, the electrons and protons are characterized by another movement in
opposite directions longitudinally, generating a current called the ring current. On
the Earth the effects of this current can be observed and measured as variations in
the geomagnetic field.