Quantum entropy of categories of Graceli.

'Entropy' as the tendency of open systems to 'evolve' into disorder, the second thermodynamic law explains how, in any isolated system, the amount of entropy tends to increase ...

However, the entropy tends to a limit point, and then decreases progressively, as the temperature falls on an iron plate the entropy tends to increase, but decreases as the temperature decreases.

And this increase also varies from material to material, of type of atom and isotope to type of material and isotopes, and according to the categories and parameters of Graceli, with this the entropy is relative, limited and transcendent.


A mirror can break into several pieces, but the collection of broken pieces, will not, by itself, reassemble in a mirror

However, the pieces are due to the intensity of the force, distance and categories of the mirror, such as type, thickness, materials and energies that bind the atoms of the mirror, and others,

The pieces can be broken forming a chain system, but new forces and energies will be needed.

That is, if there is a relativistic entropy of chains and categories. However, it is not a system in which entropy does not require external energies.


Regardless of whether the mirror is broken, or a thermal expansion, the entropy already exists within the system itself, but remains in a quantum flux of oscillations and randomness.

In a system where it is maintained by the very energy within it. In a process of chains, categories and parameters of Graceli.

However, entropy does not proceed at the same intensity of expansion, and these of vibratory flows, one connected to the other, are already processed in varied effects, and according to chains, categories and parameters of Graceli.


One type of material, or molecule and chemical element may have a larger entropy dilation, and medium quantum vibrational fluxes between the two.

And the opposite may occur in other types of materials, this can be compared between crystals, mercury, and iron, or even thorium with tunneling actions and more intense radioactivities with temperature increases.


This changes the entropy parameters, and leads to other thermodynamic parameters, as well as electrodynamics and quantum electrodynamics, and Graceli's radiodynamics.



That is, entropy exists not only in thermodynamics, but also in other branches such as quantum, electrodynamics and quantum electrodynamics, and Graceli's radiodynamics.