Thermo-electromagnetism Graceli.

Trans-intermechanical Graceli transcendent and indeterminate.
Effects 10,573 to 10,580.

Graceli theorists for:

1] Thermo-electromagnetic theory in ferromagnetic.

2] Thermo-electromagnetic isotope, in ferromagnetic, diamagnetic, paramagnetic.

3] Isotope-thermo-radioactive-electromagnetic-ferromagnetic.

4] Isotope-thermo-radioactive-electromagnetic-ferromagnetic-photon-electron-interactions of electron charges according to light interactions.


Where the temperature has fundamental action on conductivities, resistances, electromagnetic interactions with ions, electrons, charges, and others.

As it also has variations according to the types of structures, if isotopes, crystals, metals, diamagnetic, paramagnetic, and ferromagnetic. And others.

Another point is the interactions of charges, ions, electrons, light, and types of materials.


any variation in the electromagnetic energy in a certain volume must be accompanied by a flow of energy across the surface that limits that volume, as well as reflection and refraction of the electromagnetic wave. That will depend on the above relative and variable theories as each one in question. And according to energies, agents, phenomena and categories of Graceli.




Magnetic momentum, like curves and fluxes of magnetic frequencies in ferromagnetic, and atomic bundles diverted by variable magnetic fields, have variations according to energies [temperature, electricity, radioactivity, luminescence, dynamics and others, types of structures, temporal stages of life of the elements and stage of evolution, phenomena and according to categories of Graceli in which it involves density, intensity by time, types, levels and potentials of ion transformations and interactions, electrostatic potential, decays, tunnels, entanglements, entropy potential and enthalpies. Chains and conductivities.



the charge of the electron in thermal-magnetic systems, or in radioactive magnetic thermal system and under pressures. Or in a mist chamber system under light action [this has a thermal, electric, magnetic, radioactive effect under pressure conditions, and photoelectric effects. As well as Graceli photoelectrons [electron variations and charges as photons insert on electrons].


The fall of ionized droplets under the action of the electric field produced by a capacitor of parallel flat plates. Under conditions of thermal, electric, magnetic, radioactive, under pressure conditions, and photoelectric effects. Where the value of electron energies varies according to these agents, it also oscillates in variable fluxes according to the intensity, types and potential actions of these agents.


with approximate random fluxes of  ~ 4,03   10^-10 esu (electrostatic charge unit), for the so-called elementary electric charge.

Where is formed a trans-intermechanical variable Graceli, of random, transcendent and indeterminate flows.



1] Ferromagnetic thermoelectromagnetic theory.

2] Isotope thermo-electromagnetic, ferromagnetic, diamagnetic, paramagnetic.

3] Isotope-thermo-radioactive-electromagnetic-ferromagnetic.

4] Isotope-thermo-radioactive-electromagnetic-ferromagnetic-photon-electron-interactions of electron charges according to light interactions.

As each of the four forms of theories [cited above], or of other formations between structures and energies, there are variations on:

Photoelectron effect Graceli of the charge of the electron under the action of agents, energies, phenomena, and categories of Graceli.

Photoelectron effects of Graceli [variations of electrons and charges as photons insert on electrons].


Where there are variations of the charge of the electron according to variations and oscillations according to radiations, temperature, electromagnetism, light effects, and conditions under pressures.


Imagine a mist chamber with ionized electrons, with effects of photons on this chamber, then there will be loads of electrons according to types of electrons, electrostatic potentials of electrons, intensity and scattering of photons.


 E or, if this chamber meets with variations of thermal degrees, ranging from minus zero degree Celsius and positive degrees of temperature.


E or, the same with volts in a system where one has electric rays beams on the camera.


With variations according to categories of Graceli [by time of action, quantity, intensity, type, range, disintegration, scattering, distributions]. And correlated phenomena such as: entropy and enthalpy potential, refractions and diffractions, entanglements and tunnels, conductivities and resistances, ion and charge interactions and decays, emissions and absorptions, quantum jumps, oscillatory fluxes, and electrostatic potential,

Theory and effects Graceli for:
Decay of electrons that progressively their energy decreases according to means of low temperatures that always goes below

4,803206   10^-10 esu = 1,602177   10^-19 C (coulombs].

This occurs mainly in electrons in environments such as atmospheric. As one has the cosmic ray decays, there are also electron decays in atmospheric environments, or it can even be seen in a fog chamber.

Next to the electromagnetic, luminescent, radioactive, dynamic and thermal fields also occur variations in ions and electrons, and even in the behavior and energy of charges.

There are potentials with varying intensities of particle transcendences, as well as particle decay potentials.

Transcendences occur from electrons to positrons and vice versa.

The decays occur from protons to positrons.


Photon effect loads.

Where photons are inserted over charges and energies of the electron, these go into random and indeterminate oscillations, greatly increasing the instability of charges and electrons, and their energies, varying the number of electrons energy to more than: approximate random fluxes of ~ 4, 03 10-10 esu (electrostatic charge unit), for the so-called elementary electric charge.



These variations according to the intensity and proximity of accelerations are also in the thermal emissions and radiations, where a variation of thermal body emissions is formed as the dynamics approaches and / or distances, and according to their intensity.
with variations on electricity productions, magnetism and interactions of ions and charges, electrostatic potential, and other phenomena and forms of energies.


As the dynamics and energies increase, there is a system of transcendent and indeterminate effects. Forming a trans-intermechanic itself involving states, phenomena, and forms of energies.


In order to estimate the value of e [electron], in a rotational system it also becomes indeterminate as it increases or decreases the dynamics, and in relation to the intensity and proximity of temperature, electricity and magnetism. With variations for types of isotopes, ferromagnetic, diamagnetic, paramagnetic.


That is, the charge of the electron (e) can pass and have oscillatory fluxes as discussed above in relation to the dynamic and thermal means. Or even with variations of magnetism and electricity, with the charge having oscillations and the value above = 4.6  10-10 abc. According to the dynamics and thermal means in which it is.

This has a relation between dynamics, temperature and electromagnetism.



System of potential units of Graceli.
A system of units can be formed for powers of transcendence, decay, transformation and transmutation, emissions and interactions of ions and charges, instability of charges and ions, electrostatic charge potential, and others.

That is, a system of unity of diverse potentialities.


Another system of units for phase changes according to the potential of the chemical elements and isotopes and according to their capacities of transformations when in presence and time with energies, like thermal, electric, magnetic, dynamic, radioactive, luminescent, and others.

And potentials of phase changes of physical states and states of energies and phenomena, according to intensities, structures and categories of Graceli.

System of units of Graceli.

Units of radioactivity divided by time [quantity, intensity, type, range, disintegration], that is, if you have with it another type of unit of thermal radiation, or radioactive decays by time. [Graceli radiation unit].

The same for light, where one has the measurement for clarity in spaces completely without light, and the intensity of luminescence in relation to the dark means. [graceli unit of luminescence]. With variations for phosphorescence types luminescences.
[unit of light by time according: quantity, intensity, type, range, disintegration, scattering, distributions],