Talk:Nuclear model
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[[Image:Models1.jpg|thumb|left350px|Real Physical Models]]<nowiki>- You should have a category called "Real Physical Models" since I have built a set of them (One model per Element) and am trying to figure out how to explain them. The basic concept is that each element has a basic structure made up by the accumulation of Z (atomic number z) deuterons, on the surface of which are accumulated an A-2Z number of "excess neutrons" for each isotope A number. The Z number of accumulated deuterons provide a balanced structure in the case of the even Z numbers and a one deuteron degree of unbalance in the case of odd Z numbers. This unbalance can be partially corrected by the judicious adding of a varying numbers of "extra neutrons" to the top and/or bottom of the inner structure with only one extra neutron being permitted in any position. Accordingly, for a balanced original structure, it is much easier to maintain a balanced structure by the addition of 2 (or multiples of 2) than for the addition of odd numbers of "extra neutrons". The protocol for the accumulation of deuterons and up to 2 extra neutrons can be learned by the accumulating up to 20 of the new 3/8 inch (diameter) by 3/8 inch long Neodymium magnets around a central axis of rotation (and noting that magnets are like gears and that you cant side by side mesh 3 magnets and that parallel polarity magnets resist side by side conjunction. The accumulation of additional deuterons and extra neutrons unvolve what I call the "checkerboard protocol", where after 2 layers of checkers are accumulated in the center 4 squares (Protons on red and neutrons on black), each succeding series of deuteron additions, (adjacent red and black) requires 4 more deuterons than required by the previous series. Thus the acculation process starts with the accumulation of 2 layers of 4 nucleons, (2 deuterons) in the the center of the checkerboard, followed by additional layers with additional numbers of accumulated deuterons as follows: Layer/Deuterons 1/2, 2/2, 3/8, 4/8, 5/18, 6/18, 7/32, 8/32, for a total of 120 accumulated deuterons which is the capacity of the standard 64 square checkerboard. It is also easy to see thar with a 10x10 = 100 square checkerboard the accumulation of 2 layers of the next series would each involve the accumulation of 50 deuterons in each layer making the total accumulation values to be 170 for layer9 and 220 for layer 10. However the magnet protocol suggests that in the 3 dimensional accumulation process the successive layers do not pile up as they do on the checkerboard, but rather accumulate along a plane perpendicular to the axis of rotation of the atom and approximately in the center of balance of the longest (first) columns. This results in the creation of an octahedral structure with maximum symmetry at Z=118 and with locations for the addition of 64 "extra neutrons". I hope that this preliminary discussion will intrigue you into establishing an additional category for discussing real physical nuclear models. WFPM[[User:WFPM|WFPM]] ([[User talk:WFPM|talk]]) 04:55, 28 April 2008 (UTC)WFPM~~~~
