Talk:TFNR - 10.1.1 Material forms

Material Forms. The constructive interaction, the organization of easy and composite elementary Structures, produces the existence of systems of Structure gradually more complex at the increasing of the level of aggregation. Composite Structures aggregate in systems corresponding to atomic cores, these ones to easy Structures, the electrons, to form atoms, after molecules, compounds, mineral aggregates, material systems, heavenly bodies, cosmic structures and so on, till the material Universe in its complex in a hierarchy of always more complex systems. The material Structures can be classified in "dark matter" (extended massive Structures) and "ordinary matter" (particle s and wave). In the evolutive process towards always more complex Forms, given "appropriate environmental conditions" (e.g. energetic level, temperature, available elements, and so on), produces the appearance of systems of material Structures we define organic. The further development brings to always more complex forms that constitute the basis for the appearance of the first and more elementary living forms. By the functional point of view, as illustrated at point 4), each inorganic material fo rm can be defined "deterministic Agent". We define living being, all the systems of Agents that demonstrate, that bear a purpose (e.g. behavior influenced by the instinct or the intention of surviving). Molecules does not be considered as mere sum of atoms. They must be considered as complex forms, composed by several more elementary Material Form, the atoms, they, also, composed of interacting Structures of Information, organized in more complex forms, showing emergent collective behaviors and properties, deriving from the complex interaction of behaviors and properties of all the participating entities at all the less complex levels of Reality. In other word, we can consider a Material Form, such a molecule, as the complex pattern of organization of an Elementary Field domain, a space-time field domain, Elementary Action organized in a complex way, with nested levels of organization that, at the end, manifests itself as correlation between the microstates that describe the dynamics of the Elementary Field domain itself. Therefore, in the interested space-time domain, the spatial distribution of the intensities of the elementary fluctuations, that we call Perturbation, the first mode of expression of the Elementary Action, gives us the complex shape of the mass density distribution of that Material Form, the molecule. At the same time, the correlation of the distributions of the directions of the elementary fluctuations, that we call Translation, the second mode of expression of the Elementary Action, gives us the motion dynamics of the molecule in space-time. Then, the correlation of the distributions of the rotational directions of the elementary fluctuations, that we call Rotation, part of the third mode of expression of the Elementary Action, gives us complex shape of the charge density distribution of that Material Form. Again, the correlation of the distributions of the rotational directions of the elementary fluctuations, that we call Spin, part of the third mode of expression of the Elementary Action, gives us complex shape of the spin density distribution of that Material Form.