The magnetic field lines shown in the bar-magnet figure are not real entities, although they are frequently treated as such. A magnetic field is a continuous function that exists at every point in space. A field line is simply a means for visualizing the direction of this field. It is defined as a curve in three dimensions that is everywhere tangential to the local magnetic field. The pattern of field lines created by a bar magnet is called a dipolar field because it has the same shape as the electric field produced by two (di-) slightly separated charges (poles) of opposite sign. The dipole field of Earth is, of course, not produced by a bar magnet at its centre. As will be discussed later, it is instead produced by electric currents within Earth’s liquid core. To produce the present field, the equivalent current must be a westward equatorial loop, as shown in the bar-magnet . In SI units the dipole moment, μ, for Earth is 8.22 × 1022 A m2 (amperes times square metre). Since μ = IA (current times area), a loop the size of the liquid core (Rc = 3.48 × 106 m) would require an equivalent current of 2.16 × 109 A.
The magnetic field of a dipole is vertical along the polar axis and horizontal along the equator, as can be seen from the bar-magnet figure. These properties lead to definitions of equator and pole in Earth’s more complex field. Thus, the geomagnetic equator is defined as the line around Earth’s surface where the actual field is horizontal. Similarly, the magnetic dip poles are the two points at which the field is vertical. If observations are extended above or below the surface, the location of the equator is a surface (planar for a dipole) and the poles lie along curves.
At a given distance in a pure dipole field, the polar field is always twice the equatorial field. This is roughly true for Earth’s field. In a map showing the contours of constant total field magnitude according to a 1980 model plotted on a geographic Mercator projection, the largest fields occurred at two points in the Northern and Southern hemispheres not far from the geomagnetic poles. The weakest field occurred along the magnetic equator, with the lowest value being observed on the Atlantic coast of South America.
Several facts about Earth’s field are apparent from the total field map. First, the dipole approximating it is not exactly aligned with the rotation axis. The poles of the dipole are located roughly in northern Canada and on the coast of Antarctica rather than at the geographic poles. This implies that the dipole is tilted away from the rotation axis in a geographic meridian passing through the eastern United States. The exact tilt of the best-centred dipole is 11° away from the geographic North Pole toward North America at a longitude 71° W of Greenwich. The total field map also suggests that the field is not exactly centred in Earth, for, if it were, the field strength should be nearly constant along the Equator.
The mathematical description of a vector field on the surface of a sphere is quite complicated. In studies of Earth’s field it is usually done by multipole expansions. The field is assumed to be made of the superposition of fields from a series of poles located at the centre of Earth. The first pole in this expansion is a monopole corresponding to only one pole of a magnet. Since no magnetic monopole has ever been observed, this term is not used. The next term is the dipole, then the quadrupole, and so forth. When Earth’s field is described in this manner, it is found that the dipole term accounts for more than 90 percent of the field. If the contribution from a centred dipole is subtracted from the observed field, the residual is called the non-dipole field, or regional geomagnetic anomaly.
Current maps of the regional anomaly for various components of the magnetic field show that there is a large maximum in the South Atlantic and in Mongolia. This anomaly can be partially explained by offsetting the best-fit dipole in an appropriate manner. Anomalies such as this affect compass readings in polar regions and influence particles trapped in the outer field. They also are responsible for the separation between the locations of the dipole poles and the geomagnetic poles.
Magnetic surveys of Earth’s field have been conducted with increasing accuracy for well over 100 years. In recent times they have been conducted on approximately a 10-year schedule. For each survey it is possible to define the dipole and non-dipole components of the field. It has been found that both change systematically with time. The nature of these changes and their probable explanations are discussed below in Sources of variation in the steady magnetic field.
In the multipole description of Earth’s field, it is shown that the effects of higher-order poles decrease more rapidly with distance than those of the lower-order poles. The field of a monopole, for example, decreases as the inverse square of distance, the dipole as the inverse cube, and so on. Because of this property, it might be expected that the outer portions of Earth’s field would be almost purely dipolar. Recent spacecraft observations, however, show that this is not true. The field departs radically from that of a dipole at altitudes of only a few Earth radii.
Surface observations do not suggest that significant distortion of Earth’s field should occur close to the planet. The technique of multipole expansion makes it possible to separate the observed surface field into parts of origin internal and external to Earth. When surface observations are averaged over several years, less than 1 percent of the surface field is produced by external sources. Thus, the existence of the external distortion is surprising.
Outer magnetic field
The actual configuration of Earth’s outer magnetic field as recently determined by spacecraft shows projections of magnetic field lines into the noon–midnight meridian at a time near an equinox, as is summarized in the . At this time Earth’s rotation axis is perpendicular to the Earth–Sun line. The dipole axis will be tilted another plus or minus 11°, depending on the time of day. On the dayside of Earth the magnetic field of the planet terminates at a distance of about 10 Re (where Re is Earth’s equatorial radius of about 6,378 kilometres). The boundary that exists at this point is called the magnetopause (break in magnetic field). Outside this boundary magnetic fields and particles are present, but they belong to the Sun’s atmosphere and not to Earth’s. On the nightside the magnetic field is drawn out into a long tail consisting of two lobes separated by a 14-Re-thick sheet of particles called the plasma sheet. The plasma sheet has an inner boundary about 11 Re behind Earth. It also has upper and lower boundaries as shown. The projection of these boundaries onto the northern and southern portions of the atmosphere at about 67° magnetic latitude corresponds to two regions called the nightside auroral ovals. The aurora borealis and aurora australis (northern lights and southern lights) appear within the regions defined by the feet of these field lines and are caused by bombardment of the atmosphere by energetic charged particles. On the dayside, magnetic field lines from high latitudes split, some crossing the Equator while others cross over the polar caps. The regions where the field lines split are called polar cusps. The projection of the polar cusps on the atmosphere at about 72° magnetic latitude creates the dayside auroral ovals. Auroras can be seen in these regions in the dark hours of winter, but they are much weaker than on the nightside because the particles that produce them have much less energy. The projections of the two lobes of the magnetic tail onto the atmosphere are the polar caps.
Within the middle of Earth’s field are several other important boundaries and regions that cannot be detected by magnetic field observations. Close to Earth (1–2 Re) is the inner Van Allen radiation belt, which consists of very energetic particles created by cosmic rays. Centred at about 4–5 Re is the outer Van Allen belt, created from charged particles of both solar and atmospheric origin. Also at this distance is the plasmapause. This is a boundary in Earth’s plasma (a relatively cold gas consisting of equal numbers of electrons and positive ions) and, as such, actually constitutes a boundary in the planet’s electric field.