On Tue, May 20, 2014 at 06:09:43PM -0700, John Ross wrote: > > The Coulomb force between the two tronnies in the entron, if they were > stationary would be F = k QQ/r squared. But when we integrate the force > around the circle the integrated force becomes F(I) = k QQ/r. The attractive > and repulsive integrated forces in the diametrical are exactly equal. I do > the math to prove this in Chapter VI (page 50). This is the most important > feature of my model of our Universe. It almost seems unreal to me sometimes > that these two charges of plus e and minus e can be as close as 0.9339 X > 10-18 m to each other for billions of years and remain stable. If the > tronnies were stationary and that close the force between them would be 256 > million newtons (about 29 thousand tons)! But they are not stationary, they > are traveling faster than the speed of light in this tiny circle. This also > sounds unbelievable. This is probably why no one has in the past proposed my > solution. > >
I thought tronnies were point particles? If they are smeared out in space, like with conventional electrons in QM, then obviously there is no net attraction. But integrating around the circle just gives the time average of the tronnies' position, which is is just the centre of the circle. There is still a net attractive force towards the centre. Or did you propose balancing the Coulomb force with "centrifugal" force? Of course you have still to explain how your tronnie pair avoids the ultraviolet catastrophe. -- ---------------------------------------------------------------------------- Prof Russell Standish Phone 0425 253119 (mobile) Principal, High Performance Coders Visiting Professor of Mathematics [email protected] University of New South Wales http://www.hpcoders.com.au Latest project: The Amoeba's Secret (http://www.hpcoders.com.au/AmoebasSecret.html) ---------------------------------------------------------------------------- -- You received this message because you are subscribed to the Google Groups "Everything List" group. To unsubscribe from this group and stop receiving emails from it, send an email to [email protected]. To post to this group, send email to [email protected]. Visit this group at http://groups.google.com/group/everything-list. For more options, visit https://groups.google.com/d/optout.
