The email bellow was sent in August 2006

Peter Jones

Editor, Bauu Institute Press

CC:  Christy Frazier  ,  Nancy Kolenda  ,  A. K. Mukhopadhyay  ,  Keith Wakelam  ,  Alexander P Dubrov  ,  Benjamin Young  ,  Davide Fiscaletti  ,  Amrit Sorli & Davide Fiscaletti  ,  Vladimir Aristarkhov

Dear Peter Jones

Last week one experiment showed that the electron can be decomposed in two particles, with a technique called ARPES (Angle-Resolved Photoemission Spectroscopy)

See http://www.inovacaotecnologica.com.br/noticias/noticia.php?artigo=010110060718

Bellow it is translated a portion of the article:

"The electron has two intrinsic characteristics:  its charge and its spin.  But the scientists have discovered that these two "characteristics" are particles which can be separated from the own electron.  The spinons carry the informations of the electron's spin, while the holons carry the informations about its charge"

Such new discovery seems to confirm the proposal of the QUANTUM RING THEORY, concerning the spin of the electron.

Indeed, in my theory the electron's spin is due to its helical trajectory.  Into the neutron's structure "n=p+e", the electron loses its helical trajectory, in order that within the neutron the electron becomes a boson. 

In the neutron's decay, when the electron leaves out the proton, the free electron gets again its helical trajectory.  In such process an antineutrino is emitted, in order to keep the total angular momentum. 

By the same way, the new experiment (ARPES) is made in some conditions where a free  electron loses its helical trajectory.  In such process a neutrinho is emitted (in order to keep the total angular momentum)   Therefore, in such experiment the "holons" actually are the own electron that lost its spin, while the "spinons" actually are neutrinos.

Any way, this new experiment ARPES confirms my theory according which the electron can become a boson in special conditions, without violating the Fermi-Dirac statistics (the electron becomes a boson when it loses the helical trajectory, and in this case a neutrino is emitted). It's the case that happens in the ARPES experiment.

When the electron returns to the form of a fermion (getting back the helical trajectory), an antineutrino is emitted (it's the case that happens in the neutron's decay).