Today, the origin of the
magnetic field of stars and planets is explained by the dynamo effect. Since
Cowling’s anti-dynamo theorem has forbidden a purely axisymmetric
dynamo, scientists are all convinced today that the fluid flow in the core of a
star cannot be laminar, so it is turbulent. However, we will see in this study
that the configuration in which the conductive fluid contained in the core of a
star is in rapid rotation around an axis of symmetry is the one that best
explains the origin of the magnetic field of stars and planets. It also
explains why certain types of stars have very intense magnetic fields. Indeed,
we will show here that the magnetic field of stars and planets is created by
the electric current generated by the rotational movement of charged fluid
particles as in an electromagnet. The lines of this magnetic field are channelled
by the solid paramagnetic seed which plays the role of magnetic core in the
cores of planets and stars. The seed is composed mainly of Iron and Nickel on the planets and of solid
helium-3 in the stars. In this work, we will use this model of rapidly rotating
fluids to introduce a new way to ionize a neutral gas and maintain it in a
plasma state for indefinitely large time scales, to present a new technique for
generating very intense magnetic fields, to establish a new magnetic nucleation
process and to propose a new type of nuclear fusion reactor in which the plasma
is perpetually rapidly rotating.
References
[1]
Fauve, S. (2005) Effet dynamo: de la production industrielle d’électricité au champ magnétique des étoiles. La jaune et la rouge · août-septembre 2005, 56-59.
[2]
Shneider, C. (2011) Cowling’s Theorem. Leiden University, Leiden.
[3]
Hide, R. and Palmert, T.N. (1982) Generalization of Cowling’s Theorem. Geophysical and Astrophysical Fluid Dynamics, 19, 301-309. https://doi.org/10.1080/03091928208208961
[4]
Sorongane, E.W. (2022) The Catastrophe of Rapidly Rotating Fluids. Open Journal of Applied Sciences, 12, 469-480. https://doi.org/10.4236/ojapps.2022.124032
[5]
Rainbault, J.-J. (2011) Introduction to Plasma Physics. Paris-Sud University, Paris.
[6]
Berhanu, M., Bourgoin, M. and Chiffaudel, A. (2007) The VKS 2 Experiment: Observation of a Turbulent Dynamo and Erratic Magnetic Field Reversals. Reflections of Physics, 3, 14-16.
[7]
Sorongane, E.W. (2022) Implementation of a Semi-Classical Theory for Superconductors. Open Journal of Applied Sciences, 12, 1243-1253. https://doi.org/10.4236/ojapps.2022.127084
[8]
Nore, C., Guermond, J.-L., Léorat, J. and Luddens, F. (2014) Dynamo Effect in Cylindrical Geometries. Electrical Engineering Symposium, Gif-sur-Yvette, 8-10 July 2014, 7-9.
[9]
Bell, J. (2013) The Space Book: From the Beginning to the End of Time, 250 Milestones in the History of Space and Astronomy. Sterling Publishing Co., New York.
[10]
Sorongane, E.W. (2022) Electromagnetic Interaction: A New Theoretical Approach. Open Journal of Applied Sciences, 12, 491-500. https://doi.org/10.4236/ojapps.2022.124034
[11]
Cohen, Y. (1962) A New Class of Drugs: The Radioactive Isotopes. Saclay Nuclear Studies Center, Gif-Sur-Yvette.
[12]
Sourie, A. (2017) Superfluid Models of Neutron Stars in General Relativity: Applications to Pulsar Dynamics. Paris Observatory, Paris.
[13]
Channel, N. (2004) Entrainment in the Shell of a Neutron Star. Pierre and Marie Curie University, Paris.
[14]
Sorongane, E.W. (2022) Implementation of a Classical Theory for Superfluids. Open Journal of Applied Sciences, 12, 1254-1261. https://doi.org/10.4236/ojapps.2022.127085
[15]
Basdevant, J.-L., Rich, J. and Spiro, M. (2002) Nuclear Energy. Editions de l’Ecole polytechnique, Paris.
[16]
Landesman, A. (1970) Propriétés de l’hélium solidehélium solide: Propriétés générales et résonance magnétique dans l’hélium trois. Journal of Physics Colloquia, 31, 55-66. https://doi.org/10.1051/jphyscol:1970305
[17]
Guettafi, A. (2001) Concept of the Rotating Field in Alternating Current Electrical Machines: Windings. University of Batna, Batna.
[18]
Dubois, J., Diament, M. and Cogné, J.P. (2011) Geophysics: Course and Corrected Exercises. Dunod, Paris.
