This stability of an atomic formation is based on the ability of any individual graviton core to make positive symmetrical groupings.

The first prime stable bond is the quadruple bonding stack, this is a four part bond which can be represented by the points of an equilateral pyramid. This gives a ridged stable bond where each core has a connection to three of the other cores.

From this first stable core bond (Beryllium) additional cores can attach themselves in a similar three point attachment at a position above each face of the hypothetical pyramid. The distance between these new atomic spikes being the same as the original cores.

Distance here is the objective, the core spacing will be the minimum possible consistent with symmetrical graviton attraction, each graviton connection must be equal or the core would be pulled apart by the stronger, shortest, of the connections.

The atomic spikes can attach one at a time until each face has one atomic spike, at this point we reach the second stable atom. (oxygen)

The stages in between, where the core is accepting its fifth, sixth and seventh atomic spike, the atom is not symmetrical and therefore not as stable and the atom can loose an element more readily than when at its stable point where the symmetry is regained.

This process of adding atomic spikes continues each new core fixing its self at a point where it can have three connections equidistant apart on the next particle stack.

each adding until the next stable element is reached Silicon¹ (14)

PARTICLE FLOW IN MATERIALS

There are many different possibilities of atomic core stacking but the second most significant is the four sided double pyramid stack. This is based on a reflected four side double pyramid as opposed to the three sided single pyramid. This four sided stack has one significant feature in that it has a void at the center of the core. If we look at the arrangement of the core bonding we see it obeys the rules of symmetrical core gravimetric bonding but a tension is held around the void at the crater. The significance of this being that the top and bottom points are running in opposite phase rotation, this would make two similar atoms in this formation tend to orientate with each other top to bottom or as we would think of it north to south.

This type of core bonding stack will build in the same way as other stacks adding single spikes at symmetrical positions until the next stack layer is complete. If we build up to the next full stack layer we find we have fourteen spikes, the element silicon, this of course is a second silicon as we have seen silicon can also be built up on the beryllium stack. These are the same element but a variant and will behave in a slightly different way.

The next stable element on this stack is iron (26), here the strength of orientation is increased by the larger number of core bonds holding round the void with the top half in reverse phase. This stack has one particular attribute, it can add one spike at the top and one spike at the bottom while remaining in symmetry. This reinforces the orientation of these two elements, cobalt (27) , and nickel (28).