The Spinning Electron - Revision history

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	[[Category:Relativity]]		[[Category:Relativity\|spinning electron]]

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	\| title = The Spinning Electron		\| title = The Spinning Electron
	\| author = [[Martin Rivas]]		\| author = [[Martin Rivas]]
	~~\| keywords = [[Electron]], [[Toroidal ring]]~~
	\| published = 2005		\| published = 2005
	\| journal = [[None]]		\| journal = [[None]]
			\| pages = 59-82
	}}		}}

	==Abstract==		==Abstract==

	~~From <em>[/php/DatabaseMenu~~.~~php~~?~~bookid=483&tab=3 <em>What~~ is the ~~Electron?</em>]</em> (ed~~. ~~[/php/DatabaseMenu~~.~~php?tab~~=1~~&memberid=594 Volodimir Simulik]~~, ~~2005),  pp. 59~~-82.		A classical model for a spinning electron is described. It has been obtained within a kinematical formalism proposed by the author to describe spinning particles. The model satisfies Dirac?s equation when quantized. It shows that the charge of the electron is concentrated at a single point but is never at rest. The charge moves in circles at the speed of light around the centre of mass. The centre of mass does not coincide with the position of the charge for any classical elementary spinning particle. It is this separation and the motion of the charge that gives rise to the dipole structure of the electron. The spin of the electron contains two contributions. One comes from the motion of the charge, which produces a magnetic moment. It is quantized with integer values. The other is related to the angular velocity and is quantized with half integer values. It is exactly half the first one and points in the opposite direction. When the magnetic moment is written in terms of the total observable spin. one obtains the g = 2 gyromagnetic ratio. A short range interaction between two classical spinning electrons is analysed. It predicts the formation of spin 1 bound states provided some conditions on their relative velocity and spin orientation are fulfilled, thus suggesting a plausible mechanism for the formation of a Bose-Einstein condensate.

	~~A classical model for a~~ spinning electron is described.  It has been obtained within a kinematical formalism proposed by the author to describe spinning particles.  The model satisfies Dirac?s equation when quantized.  It shows that the charge of the electron is concentrated at a single point, but is never at rest.  The charge moves in circles at the speed of light around the centre of mass.  The centre of mass does not coincide with the position of the charge for any classical elementary spinning particle.  It is this separation and the motion of the charge that gives rise to the dipole structure of the electron.  The spin of the elecvtron contains two contributions.  One comes from the motion of the charge, which produces a magnetic moment.  It is quantized by integer values.  The other is related to the angular velocity and is quantized with half integer values.  It is exactly half the first one and points in the opposite direction.  When the magnetic moment is written in terms of the total observable spin, one obtains the g = 2 gyromagnetic ratio.  A short range interaction between two classical spinning electrons is analysed.  It predicts the formation of spin 1 bound states provided some conditions on their relative velocity and spin orientation are fulfilled, thus suggesting a plausible mechanism for the formation of a Bose-Einstein condensate.		[[Category:Scientific Paper\|spinning electron]]

	[[Category:~~Scientific Paper]]~~		[[Category:Relativity]]

	~~[[Category:Structure~~]]

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2016-12-30T16:31:47Z

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{{Infobox paper
| title = The Spinning Electron
| author = [[Martin Rivas]]
| keywords = [[Electron]], [[Toroidal ring]]
| published = 2005
| journal = [[None]]
}}

==Abstract==

From <em>[/php/DatabaseMenu.php?bookid=483&tab=3 <em>What is the Electron?</em>]</em> (ed. [/php/DatabaseMenu.php?tab=1&memberid=594 Volodimir Simulik], 2005),  pp. 59-82.

A classical model for a spinning electron is described.  It has been obtained within a kinematical formalism proposed by the author to describe spinning particles.  The model satisfies Dirac?s equation when quantized.  It shows that the charge of the electron is concentrated at a single point, but is never at rest.  The charge moves in circles at the speed of light around the centre of mass.  The centre of mass does not coincide with the position of the charge for any classical elementary spinning particle.  It is this separation and the motion of the charge that gives rise to the dipole structure of the electron.  The spin of the elecvtron contains two contributions.  One comes from the motion of the charge, which produces a magnetic moment.  It is quantized by integer values.  The other is related to the angular velocity and is quantized with half integer values.  It is exactly half the first one and points in the opposite direction.  When the magnetic moment is written in terms of the total observable spin, one obtains the g = 2 gyromagnetic ratio.  A short range interaction between two classical spinning electrons is analysed.  It predicts the formation of spin 1 bound states provided some conditions on their relative velocity and spin orientation are fulfilled, thus suggesting a plausible mechanism for the formation of a Bose-Einstein condensate.

[[Category:Scientific Paper]]

[[Category:Structure]]