Quantum Electrodynamics category Graceli ["Quantum Electrodynamics categorial Graceli" (QEDCG)]
the electromagnetic interaction between charged particles, involving the exchange of the particle called photon (γ), non-massive and spin 1 (boson) + phenomena, transformations, potential, states of Graceli and others according to the categories of Graceli.
and for a system of renomralization one has the existential renormalization of Graceli, if it exists and does not exist at the same time. [see published on the internet]. [which deals with the elimination of the infinite].
Renormalization is also part of the trans-indeterminate system of Graceli, where it can not be said that at one point a particle or phenomenon, or time or space, and finite or infinitely continuous, that is, renormalization is indeterminate.
The entropy in turn is finite, reaches a limit and for, however, there will be no return to the exit point, nor in the progression of entropic advancement.
That is, it has a limit, but it is irreversible [Graceli's paradox of reversibility and irreversibility].
That is, it is not only the electromagnetic interactions, but other phenomena that are involved in the processes of quantum electromagnetism.
Phenomena such as:
The potential states of quantum, magnetic and electrical resistance, ion, energy and charge interactions, electrostatics, transformations, momentum and inertial, tunneling and entanglement, diffraction and refraction, deflection and reflection, particulate and wave emissions , conductivity and radiations, entropies and enthalpies, quantum and vibratory fluxes, transmutations and decays, energy transformations, and others.
And according to phenomena, structures, energies, transcendent and potential states, phenomenal dimensionaliade of Graceli, and conformed in the categories of Graceli.
And according to the categories of Graceli of types, levels and potentials. Quantity, density, time of action, distributions and spreading potential.
Thus, there is a trans-intermechanical and indeterminate trans-intermechanic with variational effects and chains with and on the tunnels, entanglement, ion and charge interactions, dissipative transformations and energies, electrostatic effects, entropies and enthalpies, wave emissions, transformations in other forms of energies such as from electric to magnetic and vice versa, or thermal, or dynamic, etc. light decays with varied flows, quantum and vibratory flows, chains among all with varied flows, and others.
The categories are:
[eeeeeffdp [f] [mcCdt] [+ mf] [cG]. The categorical equation of Graceli.
[+ Cmf] = colors, media and shapes.
Where is formed thus, atoms and particles, radiations and waves according to vacancies and valences and these according to categories.
2) Standard Model (GWS) - It is a TG that studies the unification between electromagnetic and weak interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 (between spinrons 1) between hadrons ( baryons and mesons) and leptons.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only the weak and electromagnetic interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 [between spinrons (bosons)] between hadrons (baryons and mesons) and leptons.
3) Quantum Chromodynamics * "Quantum Chromodynamics" (QCD) - It is a TG that studies the strong interaction between quarks and antiquarks, involving the exchange of the particle called glúon (g), non-massive, spin 1 (boson) and in number of eight.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only other elements and agents of Graceli and their categories and not only the strong interaction between quarks and antiquarks, involving the exchange of the particle called gluon (g) , non-massive, of spin 1 (boson) and in number of eight.
And for The second analytical extension of (it) happened in the development of Quantum Statistical Mechanics. Let's see how. In 1865 (Annalen der Physik und Chemie 125, page 353), the German physicist Rudolf Julius Emmanuel Clausius (1822-1888) defined the Second Law of Thermodynamics (SLT) by means of the entropy function (S) as follows: Δ S ≥ 0, where the sign (=) indicates irreversible processes (which do not admit this reversal). However, while reversible processes are explained by Newton's Second Law (SLN) (linear case: Fx = m d2x / dt2, since it does not change when t = - t, which characterizes reversibility), the same does not happen with irreversible processes. Although these processes involve collision of particles and, therefore, promoting given configuration of positions and velocities of the same. Since these collisions are governed by the SLN, then the velocity inversion could then occur and thus return to an earlier situation. However, although this situation is mechanically possible, it is highly unlikely, and has never been observed in Nature, up to the present time. If this were possible, we could suffocate ourselves, for suddenly and spontaneously the vacuum could occur near our nose.
The Graceli system argues that there is no temporal, spatial reversal [because time will be another], nor entropic and phenomenal reversal [since the intensities and the epochs and spaces will be the others, forming an interminable transcendent system [trans-indeterminate Graceli [STIG]].
The Analytical Extension of Time (it) in Physics.
Quantum Electrodynamics category Graceli ["Quantum Electrodynamics categorial Graceli" (QEDCG)]
the electromagnetic interaction between charged particles, involving the exchange of the particle called photon (γ), non-massive and spin 1 (boson) + phenomena, transformations, potential, states of Graceli and others according to the categories of Graceli.
and for a system of renomralization one has the existential renormalization of Graceli, if it exists and does not exist at the same time. [see published on the internet]. [which deals with the elimination of the infinite].
Renormalization is also part of the trans-indeterminate system of Graceli, where it can not be said that at one point a particle or phenomenon, or time or space, and finite or infinitely continuous, that is, renormalization is indeterminate.
The entropy in turn is finite, reaches a limit and for, however, there will be no return to the exit point, nor in the progression of entropic advancement.
That is, it has a limit, but it is irreversible [Graceli's paradox of reversibility and irreversibility].
That is, it is not only the electromagnetic interactions, but other phenomena that are involved in the processes of quantum electromagnetism.
Phenomena such as:
The potential states of quantum, magnetic and electrical resistance, ion, energy and charge interactions, electrostatics, transformations, momentum and inertial, tunneling and entanglement, diffraction and refraction, deflection and reflection, particulate and wave emissions , conductivity and radiations, entropies and enthalpies, quantum and vibratory fluxes, transmutations and decays, energy transformations, and others.
And according to phenomena, structures, energies, transcendent and potential states, phenomenal dimensionaliade of Graceli, and conformed in the categories of Graceli.
And according to the categories of Graceli of types, levels and potentials. Quantity, density, time of action, distributions and spreading potential.
Thus, there is a trans-intermechanical and indeterminate trans-intermechanic with variational effects and chains with and on the tunnels, entanglement, ion and charge interactions, dissipative transformations and energies, electrostatic effects, entropies and enthalpies, wave emissions, transformations in other forms of energies such as from electric to magnetic and vice versa, or thermal, or dynamic, etc. light decays with varied flows, quantum and vibratory flows, chains among all with varied flows, and others.
The categories are:
[eeeeeffdp [f] [mcCdt] [+ mf] [cG]. The categorical equation of Graceli.
[+ Cmf] = colors, media and shapes.
Where is formed thus, atoms and particles, radiations and waves according to vacancies and valences and these according to categories.
2) Standard Model (GWS) - It is a TG that studies the unification between electromagnetic and weak interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 (between spinrons 1) between hadrons ( baryons and mesons) and leptons.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only the weak and electromagnetic interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 [between spinrons (bosons)] between hadrons (baryons and mesons) and leptons.
3) Quantum Chromodynamics * "Quantum Chromodynamics" (QCD) - It is a TG that studies the strong interaction between quarks and antiquarks, involving the exchange of the particle called glúon (g), non-massive, spin 1 (boson) and in number of eight.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only other elements and agents of Graceli and their categories and not only the strong interaction between quarks and antiquarks, involving the exchange of the particle called gluon (g) , non-massive, of spin 1 (boson) and in number of eight.
2) Standard Model (GWS) - It is a TG that studies the unification between electromagnetic and weak interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 (between spinrons 1) between hadrons ( baryons and mesons) and leptons.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only the weak and electromagnetic interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 [between spinrons (bosons)] between hadrons (baryons and mesons) and leptons.
3) Quantum Chromodynamics * "Quantum Chromodynamics" (QCD) - It is a TG that studies the strong interaction between quarks and antiquarks, involving the exchange of the particle called glúon (g), non-massive, spin 1 (boson) and in number of eight.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only other elements and agents of Graceli and their categories and not only the strong interaction between quarks and antiquarks, involving the exchange of the particle called gluon (g) , non-massive, of spin 1 (boson) and in number of eight.
And for The second analytical extension of (it) happened in the development of Quantum Statistical Mechanics. Let's see how. In 1865 (Annalen der Physik und Chemie 125, page 353), the German physicist Rudolf Julius Emmanuel Clausius (1822-1888) defined the Second Law of Thermodynamics (SLT) by means of the entropy function (S) as follows: Δ S ≥ 0, where the sign (=) indicates irreversible processes (which do not admit this reversal). However, while reversible processes are explained by Newton's Second Law (SLN) (linear case: Fx = m d2x / dt2, since it does not change when t = - t, which characterizes reversibility), the same does not happen with irreversible processes. Although these processes involve collision of particles and, therefore, promoting given configuration of positions and velocities of the same. Since these collisions are governed by the SLN, then the velocity inversion could then occur and thus return to an earlier situation. However, although this situation is mechanically possible, it is highly unlikely, and has never been observed in Nature, up to the present time. If this were possible, we could suffocate ourselves, for suddenly and spontaneously the vacuum could occur near our nose.
The Graceli system argues that there is no temporal, spatial reversal [because time will be another], nor entropic and phenomenal reversal [since the intensities and the epochs and spaces will be the others, forming an interminable transcendent system [trans-indeterminate Graceli [STIG]].
Quantum Electrodynamics category Graceli ["Quantum Electrodynamics categorial Graceli" (QEDCG)]
the electromagnetic interaction between charged particles, involving the exchange of the particle called photon (γ), non-massive and spin 1 (boson) + phenomena, transformations, potential, states of Graceli and others according to the categories of Graceli.
and for a system of renomralization one has the existential renormalization of Graceli, if it exists and does not exist at the same time. [see published on the internet]. [which deals with the elimination of the infinite].
Renormalization is also part of the trans-indeterminate system of Graceli, where it can not be said that at one point a particle or phenomenon, or time or space, and finite or infinitely continuous, that is, renormalization is indeterminate.
The entropy in turn is finite, reaches a limit and for, however, there will be no return to the exit point, nor in the progression of entropic advancement.
That is, it has a limit, but it is irreversible [Graceli's paradox of reversibility and irreversibility].
That is, it is not only the electromagnetic interactions, but other phenomena that are involved in the processes of quantum electromagnetism.
Phenomena such as:
The potential states of quantum, magnetic and electrical resistance, ion, energy and charge interactions, electrostatics, transformations, momentum and inertial, tunneling and entanglement, diffraction and refraction, deflection and reflection, particulate and wave emissions , conductivity and radiations, entropies and enthalpies, quantum and vibratory fluxes, transmutations and decays, energy transformations, and others.
And according to phenomena, structures, energies, transcendent and potential states, phenomenal dimensionaliade of Graceli, and conformed in the categories of Graceli.
And according to the categories of Graceli of types, levels and potentials. Quantity, density, time of action, distributions and spreading potential.
Thus, there is a trans-intermechanical and indeterminate trans-intermechanic with variational effects and chains with and on the tunnels, entanglement, ion and charge interactions, dissipative transformations and energies, electrostatic effects, entropies and enthalpies, wave emissions, transformations in other forms of energies such as from electric to magnetic and vice versa, or thermal, or dynamic, etc. light decays with varied flows, quantum and vibratory flows, chains among all with varied flows, and others.
The categories are:
[eeeeeffdp [f] [mcCdt] [+ mf] [cG]. The categorical equation of Graceli.
[+ Cmf] = colors, media and shapes.
Where is formed thus, atoms and particles, radiations and waves according to vacancies and valences and these according to categories.
2) Standard Model (GWS) - It is a TG that studies the unification between electromagnetic and weak interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 (between spinrons 1) between hadrons ( baryons and mesons) and leptons.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only the weak and electromagnetic interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 [between spinrons (bosons)] between hadrons (baryons and mesons) and leptons.
3) Quantum Chromodynamics * "Quantum Chromodynamics" (QCD) - It is a TG that studies the strong interaction between quarks and antiquarks, involving the exchange of the particle called glúon (g), non-massive, spin 1 (boson) and in number of eight.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only other elements and agents of Graceli and their categories and not only the strong interaction between quarks and antiquarks, involving the exchange of the particle called gluon (g) , non-massive, of spin 1 (boson) and in number of eight.
2) Standard Model (GWS) - It is a TG that studies the unification between electromagnetic and weak interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 (between spinrons 1) between hadrons ( baryons and mesons) and leptons.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only the weak and electromagnetic interactions, involving the exchange of photons (γ) and the massive particles W - and Z0 [between spinrons (bosons)] between hadrons (baryons and mesons) and leptons.
3) Quantum Chromodynamics * "Quantum Chromodynamics" (QCD) - It is a TG that studies the strong interaction between quarks and antiquarks, involving the exchange of the particle called glúon (g), non-massive, spin 1 (boson) and in number of eight.
As mentioned above, there are other agents, phenomena and categories of Graceli and not only other elements and agents of Graceli and their categories and not only the strong interaction between quarks and antiquarks, involving the exchange of the particle called gluon (g) , non-massive, of spin 1 (boson) and in number of eight.
And for The second analytical extension of (it) happened in the development of Quantum Statistical Mechanics. Let's see how. In 1865 (Annalen der Physik und Chemie 125, page 353), the German physicist Rudolf Julius Emmanuel Clausius (1822-1888) defined the Second Law of Thermodynamics (SLT) by means of the entropy function (S) as follows: Δ S ≥ 0, where the sign (=) indicates irreversible processes (which do not admit this reversal). However, while reversible processes are explained by Newton's Second Law (SLN) (linear case: Fx = m d2x / dt2, since it does not change when t = - t, which characterizes reversibility), the same does not happen with irreversible processes. Although these processes involve collision of particles and, therefore, promoting given configuration of positions and velocities of the same. Since these collisions are governed by the SLN, then the velocity inversion could then occur and thus return to an earlier situation. However, although this situation is mechanically possible, it is highly unlikely, and has never been observed in Nature, up to the present time. If this were possible, we could suffocate ourselves, for suddenly and spontaneously the vacuum could occur near our nose.
The Graceli system argues that there is no temporal, spatial reversal [because time will be another], nor entropic and phenomenal reversal [since the intensities and the epochs and spaces will be the others, forming an interminable transcendent system [trans-indeterminate Graceli [STIG]].
A Extensão Analítica do Tempo (it) na Física.
Eletrodinâmica Quântica categorial Graceli [“Quantum Electrodynamics categorial Graceli”(QEDCG)]
a interação eletromagnética entre partículas carregadas, envolvendo a troca da partícula chamada de fóton (γ), não-massiva e de spin 1 (bóson) + fenômenos, transformações, potenciais, estados de Graceli e outros conforme as categorias de Graceli.
e para um sistema de renomralização se tem ¨a renormalização existencial de Graceli¨, se que existe e não existe ao mesmo tempo. [ver publicado na internet]. [que trata da eliminação dos infinitos].
A renormalização também faz parte do sistema trans-indeterminado de Graceli, onde não se pode afirmar que num ponto de uma partícula ou fenômeno, ou tempo ou espaço e finito ou continua infinitamente, ou seja, a renormalização é indeterminada.
A entropia por sua vez é finita, chega a um limite e para, porem, não haverá um retorno ao ponto de saída, e nem na progressão de avanço entrópico.
Ou seja, ela tem limite, mas é irreverssivel [paradoxo Graceli de reverssibilidade e irreverssibilidade].
Ou seja, não é apenas as interações eletromagnetica, mas outros fenômenos que estão envolvidos nos processos de quantum eletromagnetismo.
Fenômenos como:
Os estados potenciais quântico, resistência magnética e elétrica, de interações de íons, energias e cargas, de eletrostática, de transformações, de momentum e inercial, de tunelamento e emaranhamento, de difração e refração, deflexão e reflexão, de emissões de partículas e ondas, de condutividade e radiações, entropias e entalpias, de fluxos quântico e vibratório, transmutações e decaimentos, transformações de energias, e outros.
E conforme fenômenos, estruturas, energias, estados transcendentes e potenciais, dimensionaliade fenomênica de Graceli, e conforme nas categorias de Graceli.
E conforme as categorias de Graceli de tipos, níveis e potenciais. Quantidade, densidade, tempo de ação, distribuições e potencial de espalhamnto.
E assim se tem uma trans-intermecânica transcendente e indeterminada com efeitos variacionais e cadeias com e sobre os tunelamentos, emaranhamento, interações de íons e cargas, transformações e energias dissipativas, efeitos eletrostático, entropias e entalpias, emissões de ondas, transformações em outras formas de energias como de elétrica para magnética e vice-versa, ou térmica, ou dinâmica, etc. decaimentos leves com fluxos variados, fluxos quântico e vibratório, cadeias entre todos com fluxos variados, e outros.
Sendo as categorias:
[eeeeeffdp[f][mcCdt][+mf][cG]. A equação categorial de Graceli.
[+Cmf] = cores, meios e formas.
Onde se forma assim, átomos e partículas, radiações e ondas conforme vacâncias e valências e estas conforme categorias.
2) Modelo Padrão (GWS) – É uma TG que estuda a unificação entre as interações eletromagnética e fraca, envolvendo a troca de fótons (γ) e as partículas massivas W - e Z0± [de spin 1 (bósons)] entre hádrons (bárions e mésons) e léptons.
Como o exposto acima se tem outros agentes, fenômenos e categorias de Graceli e não apenas as interações eletromagnética e fraca, envolvendo a troca de fótons (γ) e as partículas massivas W - e Z0± [de spin 1 (bósons)] entre hádrons (bárions e mésons) e léptons.
3) Cromodinâmica Quântica *“Quantum Chromodynamics” (QCD)] – É uma TG que estuda a interação forte entre quarks e antiquarks, envolvendo a troca da partícula chamada de glúon (g), não-massiva, de spin 1 (bóson) e em número de oito.
Como o exposto acima se tem outros agentes, fenômenos e categorias de Graceli e não apenas se tem outros elementos e agentes de Graceli e suas categorias e não apenas a interação forte entre quarks e antiquarks, envolvendo a troca da partícula chamada de glúon (g), não-massiva, de spin 1 (bóson) e em número de oito.
E para A segunda extensão analítica de (it) aconteceu no desenvolvimento da Mecânica Estatística Quântica. Vejamos como. Em 1865 (Annalen der Physik und Chemie 125, p. 353), o físico alemão Rudolf Julius Emmanuel Clausius (1822-1888) definiu a Segunda Lei da Termodinâmica (SLT) por intermédio da função entropia (S) da seguinte maneira: ∆ S ≥ 0, onde o sinal (=) indica processos reversíveis [que admitem a reversão temporal (t → - t)] e (>), processos irreversíveis (que não admitem essa reversão). Contudo, enquanto os processos reversíveis são explicados pela Segunda Lei de Newton (SLN) (caso linear: Fx = m d2x/dt2, pois ela não se altera quando t = - t, o que caracteriza a reversibilidade), o mesmo não acontece com os processos irreversíveis. Muito embora estes processos envolvam colisão de partículas e, portanto, promovendo dada configuração de posições e velocidades das mesmas. Ora, como essas colisões são regidas pela SLN, poderia então ocorrer a inversão das velocidades e, desse modo, voltar a uma situação anterior. Contudo, embora essa situação seja mecanicamente possível, ela é altamente improvável, e nunca foi observado na Natureza, até o presente momento. Se isso fosse possível, poderíamos nos sufocar, pois, de repente e espontaneamente, poderia ocorre o vácuo perto de nosso nariz.
O sistema de Graceli defende que não existe reversão tempotal, e espacial [pois o tempo será outro], e nem reversão entrópico e fenomênico [pois, as intensidades e os eagentes, e espaços seroa outros, formando um sistema transcendente interminado [trans-indeterminado Graceli [STIG]].