Monday, April 20, 2015

Three Proton Bit Cycles From One Positron Spot

A single positron spot in a spot cube [1] can participate in three proton bit cycles in neighboring spot cubes adjacent to the home spot cube of the positron spot as previously reported [2]. The video below shows this phenomenon with the freely downloadable Binary Mechanics Lab Simulator v1.36.8.

Each proton bit cycle has a duration of 21 simulator Ticks, each of which has four sub-ticks t, one for each fundamental bit operation in binary mechanics [3]. During this 84t proton cycle (21 x 4), a 1-state bit occupies 42 bit loci locations, half of which are mite (fermion) loci and half are lite (boson) loci.

In the video, the three lite bits in the positron spot are synchronized at the initial T = 0 state. This might be a somewhat unusual case, since three 1-state bits may pass through the home positron spot at different times as well. In addition, these proton cycles are probably populated with more than a single 1-state bit in naturally occurring protons, a subject which is presently being examined in more detail.

The demo video shows the bit motion in an absolute vacuum [4] and clearly the proton can exist in such a low vacuum density environment and its life-time is infinite [5].

If a proton bit cycle in this positron home cube were added along with two electron spots in two of these four spot cubes, a four nucleon object would be forming corresponding to the stable helium nucleus. Perhaps the role of a single positron spot in a home spot cube in proton bit cycles in three adjacent spot cubes has a particular significance in nuclear physics as hadron states are studied further in more detail.

[1] Keene, J. J. "Physical interpretation of binary mechanical space" J. Bin. Mech. February, 2011.
[2] Keene, J. J. "Proton and electron bit cycles" J. Bin. Mech. April, 2015.
[3] Keene, J. J. "Fundamental forces in physics" J. Bin. Mech. October, 2014.
[4] Keene, J. J. "Vacuum thresholds" J. Bin. Mech. March, 2011.
[5] Keene, J. J. "Solved physics mysteries" June, 2011.
© 2015 James J Keene