Help, in particular as regards using the blog facility is to added on occasions.

A. Blog Usage:
1. Add a user account with name and password to write a blog
2. The name can be part of the person’s name for the brave and open. An arbitrary name can also be chosen.
3. All contributions relating to physics, whatever name is used, are welcome.

B. Hosting:
1. The site is hosted on WordPress facilities
2. The P2 Classic theme from Automation is being used

Proton1

The proton structure of two up and one down quark is accepted as it also was in the standard model. Each quark is however, similar to the electron, a rotating turning ring of smaller particles, named eens, with electric charges of much smaller magnitude than that of the whole electron. The rotation is a spin about a moving axis through the centre of the ring normal to the plane of the ring. The turning is about a steady axis forming a diagonal of the ring, which is also along the spin direction of the quark. The smaller particles along the perimeter of the ring also spin in pairs or larger groups about axes locally tangential to the ring. Each component angular motion is at a frequency such that the resulting component of velocity at the rings circumference is at a speed of the order of c, the speed of light in a vacuum. The turn rate gives rise to what is known as the ‘zitterbewegung’ frequency. Photons have two counter rotating rings of opposite net electric charge staying in close proximity to each other. These also turn at the rate usually attributed as the frequency of the photon. Electrons and quarks are thought to have a mixture of large numbers of positive, negative and neutral eens in repetitive sequences around their perimeters. The electrical interactions between the eens are sufficiently strong to perform what is usually ascribed to the strong force. The energy stored in the ring is dependent on the work done to squeeze the ring together. The ring diameter is dependent on the electric potential in which the ring finds itself. The ring is very thin and can deform due to mechanical interactions and electric potential gradients.