34. Dodecagraf — atomic nucleus

Dodecagraf is derived from the word “dodecahedron” and “graf” – mathematical collection of sets (as usual, “f” instead of “ph”). Dodecagraf, or just graf.

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In this section, we will present all the layers that can be formed from dodecahedrons by gradually increasing their quantity, starting with a single central dodecahedron.

We will distinguish rigid structures from ordinary non-rigid ones.

A rigid structures, so-called FROIMs is a Phenomenally Rigid Objects of the Initial Matter (see the appropriate section of this site). These structures provide strength to the whole structure of the nucleus, since they can not change its shape during collisions and under the force of external pressure.

Let us suppose that external forces are always applied centrally symmetric with respect to atoms. This is a logical assumption, since the outer atoms can be either other atoms (the maximum difference in the size of the atoms is less than 3 times), or the ether surrounding the atoms (applying the same pressure on all sides, which ensures the stability of the substance).

External forces are always directed to the compression of FROIM structures, since they are applied perpendicular to the touching faces of the dodecahedrons.

Conventional non-rigid structures from dodecahedrons are arranged at gaps inside FROIMs. Dodecahedrons of non-rigid structures can be separated from FROIMs with application of an external pressure or strokes. Since the external forces in this case are aimed at separating the dodecahedrons from each other.

All images are taken from the same distance from the camera to the Central dodecahedron. This should be considered when comparing the sizes of the components.

So layer 1 is the Central proton:

Layer 2 (12 protons located on all 12 faces of the central proton):

Since the Central proton is completely hidden from the outside world by side protons, in all subsequent structures we will not take it into account, that is, the total number of protons will always be reduced by one.

The first part of Layer 3 (rigid FROIM structure consisting of 3 layers):

Layer 3, fully filled — added 20 dodecahedrons between twelve dodecahedrons of rigid structure:

The previous image is completed with the first part of Layer 4 (rigid FROIM structure supplemented with 60 dodecahedrons):

Layer 4, fully filled — added 20 dodecahedrons (blue) between sixty dodecahedrons of rigid structure:

The previous image is supplemented with the first part of Layer 5 (rigid FROIM structure consisting of 30 yellow dodecahedrons):

The previous image was supplemented with the second part of the Layer 5 (FROIM a rigid structure consisting of 12 multi-colored dodecahedron the pentagonal centers of the rosettes):

The previous image is supplemented by the third part of Layer 5 — a structure consisting of 60 multi-colored dodecahedrons, 12 pentagonal rosettes:

The previous image is supplemented with Layer 6 (rigid FROIM structure consisting of 12 red dodecahedrons). Total number of dodecahedra (nucleons) 238 :