quantum mechanics Graceli of the energetic means. [MQGME].
EFEITO 10.730.

where the energies and types of media have fundamental action on the phenomena, such as conductivity and magnetism in iron, day and paramagnetic, and others, metals and nonmetals, ceramics, crystals, superfluidity, phase changes, renormalizations, entropies, and others, and according to the intensities, types and potentials of diverse phenomena and energies.

light has a different scattering and dispersion in water than in media under temperature, electricity, magnetism, and others.


relativism and categorialism Graceli of the dispersion of light.
10,728 effect.

variable dispersion relativistic phenomenal categorial of light.

It is interesting to note that the dispersion of light only began to be physically explained in the 19th Century. Indeed, on November 19, 1821, the French physicist Augustin Jean Fresnel (1788-1827) presented at the French Academy of Sciences a first explanation for this physical phenomenon taking into account the molecular structure of matter. Thus, for the formulator of the Light Wave Theory, the total of the luminous dispersion depended on the relation between the wavelength of light () and the distance between the adjacent molecules. It is interesting to note that in this Memoire (Annales de Chimie 17, 180), Fresnel proposed the hypothesis that the Cartesian luminiferous ether was partially dragged by matter. In view of this, he calculated the velocity of light (v) in a moving medium and, with this hypothesis, he found the following result:

v = c1 + [(n2 - 1) / n2] V,

where c1 represents the velocity of light in the resting medium (c1 = c / n), n is the refractive index of the medium, V is the velocity of the medium, and c is the velocity of light in vacuum.
                    it was the Dutch physicist Hendrik Anton Lorentz (1853-1928; PNF, 1902) who presented in 1892 the complete explanation of the dispersion by demonstrating that the refractive index (n) of a medium is given by:



n2 (ω) = (1 + 4 π N e2) / [m (ω02 - ω2)]



where m and m represent respectively the mass and charge of the electron, N is the number of molecules per unit volume of a refractive medium, is the linear frequency of the constituent electrons of the medium, around fixed positions, and the linear frequency of a monochromatic electromagnetic wave that crosses the considered medium.



relativism and categorialism Graceli of the dispersion of light.
EFEITO 10.730.

However, the dispersion of light gains other parameters when the means are constituted as energy variants [thermal, electric, magnetic, radioactive, luminescent, and variations in media under pressure and vacuum], another point is that light is a variant according to types of light (such as lasers, masers, incandescence light, radioactivity and decays) and phenomena such as electrostatic potential, emissions, etc. and photons with thermal, electrical, radioactive, chemical, biochemical origin in fireflies, and others.


that is, the light has its dispersion variables. involving types, levels, potentials, and other categories of Graceli.

relativism and categorialism Graceli of the dispersion of light.

n2 (ω) = (1 + 4 π N e2) / [m (ω02 - ω2)] p = h / λ [EF] ./ c

p = h / λ [EF], ie, variables of energies, phenomena and in relation to the speed of light.