What if electron incorporate fast revolving magnetic dipole aka a rotating bar magnet in a range of Zitterbewegung frequency? So a steady magnet near to it will experience null or to little magnetic interaction depending the angle between the dipole axis and the rotating axis, however two electrons having their dipoles rotating at same frequency will eventually pull stronglyeach other. Take two short bar magnets and figure out different sticking forms.
On the other hand the electron should be very talented to take this advantage to reach the nucleus. It definitely needs some external help by a pre alignment of shell electrons maybe to do its trick. However you (electron) can do all sort strange things if you have such a rotating strong dipole. At least theories don't having this knowledge can not presume you can not pass the Coulomb barrier. The ohmic resistance is explained by scattering of electron in metal due to electrical forces (in non magneto-resistive environment?). Is this definitely correct? If the scattering is caused mainly by magnetic forces. If you stick two bar magnets N to S and S to N the total dipole moment become zero or close, leaving higher order moments. So scattering could be eliminated this way resulting zero ohmic resistance. -----Original Message----- From: Axil Axil <janap...@gmail.com> To: vortex-l <vortex-l@eskimo.com> Date: Tue, 29 Jul 2014 02:57:49 -0400 Subject: [Vo]:The case for magnetism http://phys.org/news/2014-07-physicists-nature-high-temperature-superconductivity.html [http://phys.org/news/2014-07-physicists-nature-high-temperature-superconductivity.html] Physicists unlock nature of high-temperature superconductivity It's magnetism that eliminates the coulomb barrier that allows electrons to stick together and form cooper pairs found in superconductivity. This finding from superconductivity strengthens the case made for magnetism at the primary causation mechanism in LENR.