Past and present magnetism of the Moon
Abstract
The characteristics of the remanent magnetism of lunar samples suggests that it was acquired in a magnetic field on the Moon. The most likely origin of the field is a dynamo process in a molten, electricallyconducting core, but generation of a transient magnetic field during large meteorite impacts cannot be entirely ruled out. The magnetizing process may be thermoremanence, acquired when the rocks cooled through, the Curie point of the constituent iron grains which carry the remanent magnetization, or it may involve shock at the time of a meteorite impact, with or without a partial thermoremanence arising from heating. Evidence from absolute and relative determinations of the ancient field strength from the sample magnetizations strongly favours a global lunar field. This is implied by a trend which shows the field rising to a maximum value of ∼100 μT between about 3.9 3.7 by ago and then decaying to 5 10 μT until∼3.1 by. Such a systematic variation of field with time is not expected to be derived from magnetizations acquired in transient, impact-generated fields varying randomly in intensity. Contributory evidence for a dynamo field is provided by measurements of present lunar surface fields, the present very small dipole moment of the Moon and accumulating evidence of variation of the axis of the lunar field with time. Although there is no direct evidence for the existence of a lunar core the relevant observations are consistent with the presence of a core of up to 400 km, in radius. There are some difficulties associated with the lunar dynamo mechanism and its energy source but the evidence for a lunar dynamo is accumulating, with important implications for the structure and thermal history of the Moon.
- Publication:
-
Geophysical Surveys
- Pub Date:
- December 1984
- DOI:
- 10.1007/BF01449175
- Bibcode:
- 1984GeoSu...7...57C
- Keywords:
-
- Lunar Magnetic Fields;
- Lunar Rocks;
- Paleomagnetism;
- Remanence;
- Breccia;
- Dynamo Theory;
- Igneous Rocks;
- Lunar Evolution;
- Magnetization;
- Polar Wandering (Geology)