Evidence for long-term asymmetries in the Earth's magnetic field and possible implications for dynamo theories
Abstract
Paleomagnetic data indicate that there is a north-south asymmetry in the time-averaged magnetic field and that there are small but significant differences between the normal and reverse polarity states. The geographical variation is most likely due to spatial variation in the boundary conditions at the core-mantle interface. The difference in the magnetic fields of the reverse and normal polarity states can be modeled in terms of a "standing field". The paleomagnetic data are insufficient to determine whether or not this "standing field" is of core origin. However, consideration of mechanisms, including thermoelectric currents, indicates that there probably are important differences in core processes between the two polarity states. At first glance this interpretation is difficult to reconcile with the fact that the magnetic induction equation is antisymmetric with respect to the magnetic field. A way around this problem is the possibility that only certain transitions are allowed between acceptable eigenstates in dynamo models of the Earth's magnetic field.
Additional Information
© 1979 Elsevier Scientific Publishing Company. Accepted for publication in revised form April 2, 1979. One of us (R.T.M.) is thankful for grants from the National Science Foundation and Australian National University that allowed him to carry out this research at the Australian National University; R.T.M. Would also like to thank Dr. Frank Stacey for a useful discussion on the thermoelectric model. A review of an earlier version of this manuscript by Dr. Ken Hoffman was very helpful.Additional details
- Eprint ID
- 41957
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- CaltechAUTHORS:20131016-151213282
- NSF
- Australian National University
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2013-10-16Created from EPrint's datestamp field
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2021-11-10Created from EPrint's last_modified field
- Caltech groups
- Division of Geological and Planetary Sciences