The importance of magnetic fields in astrophysical phenomena has already been noted. It is believed that these fields are produced by self-generating dynamos, although the exact details are still not fully understood. In the case of the Earth, differential rotation in its liquid conducting core causes the external magnetic dipole field (manifest as the North and South poles). Cyclonic turbulence in the liquid, generated by heat conduction and Coriolis forces (apparent forces accompanying all rotating systems, including the heavenly bodies), generates the dipole field from these loops. Over geologic time, the Earth’s field occasionally becomes small and then changes direction, the North Pole becoming the South Pole and vice versa. During the times in which the magnetic field is small, cosmic rays can more easily reach the Earth’s surface and may affect life forms by increasing the rate at which genetic mutations occur.
Similar magnetic-field generation processes are believed to occur in both the Sun and the Milky Way Galaxy. In the Sun the circular internal magnetic field is made observable by lines of force apparently breaking the solar surface to form exposed loops; entry and departure points are what are observed as sunspots. Although the exterior magnetic field of the Earth is that of a dipole, this is further modified by currents in both the ionosphere and magnetosphere. Lunar and solar tides in the ionosphere lead to motions across the Earth’s field that produce currents, like a dynamo, that modify the initial field. The auroral oval current systems discussed earlier create even larger magnetic-field fluctuations. The intensity of these currents is modulated by the intensity of the solar wind, which also induces or produces other currents in the magnetosphere. Such currents taken together constitute the essence of a magnetic storm.
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