Physics/Essays/Fedosin/Selfconsistent gravitational constants

Self-consistent gravitational constants are complete sets of fundamental constants, which are self-consistent and define various physical quantities associated with gravitation. These constants are calculated in the same way as electromagnetic constants in electrodynamics. This is possible because in the weak field equations of general relativity are simplified into equations of gravitoelectromagnetism, similar in form to Maxwell's Equations. Similarly, in the weak field approximation equations of covariant theory of gravitation ^[1] turn into equations of Lorentz-invariant theory of gravitation (LITG). LITG equations are Maxwell-like gravitational equations, which are similar to equations of gravitoelectromagnetism. If these equations are written with the help of self-consistent gravitational constants, there is the best similarity of equations of gravitational and electromagnetic fields. Since in 19-th century there was no International System of Units, the first mention of gravitational constants was possibly due to Forward (1961).^[2]

In gravitational wave representation, the set of gravitational constants depends on the speed of propagation of gravity, in contrast to electromagnetic wave representation, in which all space-time measurements and definition of physical quantities are based on the speed of light. Primary set of gravitational constants is:

1. First gravitational constant: ${\displaystyle c_g}$, which is the speed of gravitational waves in vacuum; ^[3]

2. Second gravitational constant: ${\displaystyle {\rho }_g}$, which is the gravitational characteristic impedance of free space.

Secondary set of gravitational constants is:

1. Gravitoelectric gravitational constant (like electric constant): ${\displaystyle {\epsilon }_g=\frac{1}{4\pi G}=1.192708\cdot 10^9\mathrm{k}\mathrm{g}\mathrm{\cdot }{\mathrm{s}}^{\mathrm{2}}\mathrm{\cdot }{\mathrm{m}}^{\mathrm{-}\mathrm{3}},}$ where ${\displaystyle G}$ is gravitational constant.

2. Gravitomagnetic gravitational constant (like vacuum permeability): ${\displaystyle {\mu }_g=\frac{4\pi G}{c_g^2}.}$ If the speed of gravitation is equal to the speed of light, ${\displaystyle c_g=c,}$ then ^[4] ${\displaystyle {\mu }_{g0}=9.328772\cdot 10^{-27}\mathrm{m}/\mathrm{k}\mathrm{g}.}$

Both, primary and secondary sets of gravitational constants are selfconsistent, because they are connected by the following relationships:

${\displaystyle \frac{1}{\sqrt{{\mu }_g{\epsilon }_g}}=c_g,}$

${\displaystyle \sqrt{\frac{{\mu }_g}{{\epsilon }_g}}={\rho }_g=\frac{4\pi G}{c_g}.}$

If ${\displaystyle c_g=c,}$ then gravitational characteristic impedance of free space be equal to: ^{[5] [6]}

${\displaystyle {\rho }_{g0}=\frac{4\pi G}{c}=2.796696\cdot 10^{-18}{\mathrm{m}}^{\mathrm{2}}/\mathrm{(}\mathrm{s}\mathrm{\cdot }\mathrm{k}\mathrm{g}\mathrm{)}.}$

In Lorentz-invariant theory of gravitation the constant ${\displaystyle {\rho }_g}$ in case ${\displaystyle c_g=c}$ is contained in formula for vector energy flux density of gravitational field (Heaviside vector): ^[3]

${\displaystyle 𝐇=-\frac{c^2}{4\pi G}\mathrm{\Gamma }\times \mathrm{\Omega }=-\frac{c}{{\rho }_{g0}}\mathrm{\Gamma }\times \mathrm{\Omega },}$

where:

• ${\displaystyle \mathrm{\Gamma }}$ is gravitational field strength,
• ${\displaystyle \mathrm{\Omega }}$ is gravitational torsion field.

For plane transverse uniform gravitational wave, in which for amplitudes of field strengths holds ${\displaystyle \mathrm{\Gamma }=c_g\mathrm{\Omega }}$ according to [[../Maxwell-like gravitational equations/]], may be written:

${\displaystyle H=\frac{{\mathrm{\Gamma }}^2}{{\rho }_g}.}$

A similar relation in electrodynamics for amplitude of flux density of electromagnetic energy of a plane electromagnetic wave in vacuum, in which ${\displaystyle E=cB}$, is as follows: ^[7]

${\displaystyle S=\frac{E^2}{Z_0},}$

where ${\displaystyle 𝐒=\frac{𝐄\times 𝐁}{{\mu }_0}=\frac{c}{Z_0}𝐄\times 𝐁}$ – Poynting vector, ${\displaystyle E}$ – electric field strength, ${\displaystyle B}$ – magnetic flux density, ${\displaystyle {\mu }_0}$ – vacuum permeability, ${\displaystyle Z_0=c{\mu }_0}$ – impedance of free space.

Gravitational impedance of free space ${\displaystyle {\rho }_{g0}}$ was used in paper ^[8] to evaluate the interaction section of gravitons with matter.

Since gravitational constant and speed of light are included in Planck mass ${\displaystyle m_P=\sqrt{\frac{\hslash c}{G}}}$, where ${\displaystyle \hslash }$ – reduced Planck constant or Dirac constant, then gravitational characteristic impedance of free space can be represented as:

${\displaystyle {\rho }_{g0}=\frac{2h}{m_P^2}}$,

where ${\displaystyle h}$ – Planck constant.

There is Stoney mass, related to elementary charge ${\displaystyle e}$ and electric constant ${\displaystyle {\epsilon }_0}$:

${\displaystyle m_S=e\sqrt{\frac{{\epsilon }_g}{{\epsilon }_0}}=\frac{e}{\sqrt{4\pi G{\epsilon }_0}}}$.

Stoney mass can be expressed through the Planck mass:

${\displaystyle m_S=\sqrt{\alpha }\cdot m_P}$,

where ${\displaystyle \alpha }$ is the electric fine structure constant.

This implies another expression for gravitational characteristic impedance of free space:

${\displaystyle {\rho }_{g0}=\alpha \cdot \frac{2h}{m_S^2}}$.

Newton law for gravitational force between two Stoney masses can be written as:

${\displaystyle F_g=\frac{1}{4\pi {\epsilon }_g}\cdot \frac{m_S^2}{r^2}={\alpha }_g\cdot \frac{\hslash c}{r^2}.}$

Coulomb's law for electric force between two elementary charges is:

${\displaystyle F_e=\frac{1}{4\pi {\epsilon }_0}\cdot \frac{e^2}{r^2}=\alpha \cdot \frac{\hslash c}{r^2}.}$

Equality of ${\displaystyle F_g}$ and ${\displaystyle F_e}$ leads to equation for the Stoney mass ${\displaystyle m_S=e\sqrt{\frac{{\epsilon }_g}{{\epsilon }_0}},}$ that was stated above. Hence the Stony mass may be determined from the condition that two such masses interact via gravitation with the same force as if these masses had the charges equal to the elementary charge and only interact through electromagnetic forces.

The electric fine structure constant is:

${\displaystyle \alpha =\frac{e^2}{2{\epsilon }_{0}hc}.}$

We can determine the same value for gravitation so: ${\displaystyle {\alpha }_g=\frac{m_S^2}{2{\epsilon }_{g}hc}=\alpha ,}$ with the equality of the fine structure constants for both fields.

On the other hand, the gravitational fine structure constant for hydrogen system at the atomic level and at the level of star is also equal to fine structure constant:

${\displaystyle \alpha =\frac{G_s{M}_p{M}_e}{\hslash c}=\frac{G{M}_{ps}{M}_{\mathrm{\Pi }}}{{\hslash }_s{C}_s}=\frac{1}{137.036}}$,

where ${\displaystyle G_s}$ – strong gravitational constant, ${\displaystyle M_p}$ and ${\displaystyle M_e}$ – the mass of proton and electron, ${\displaystyle M_{ps}}$ and ${\displaystyle M_{\mathrm{\Pi }}}$ – mass of the star-analogue of proton and the planet-analogue of electron, respectively, ${\displaystyle {\hslash }_s}$ – stellar Dirac constant, ${\displaystyle C_s}$ – characteristic speed of stars matter.

The magnetic force between two fictitious elementary magnetic charges is:

${\displaystyle F_m=\frac{1}{4\pi {\mu }_0}\cdot \frac{q_m^2}{r^2}=\beta \cdot \frac{\hslash c}{r^2},}$

where ${\displaystyle q_m=\frac{h}{e}}$ is the magnetic charge, ${\displaystyle \beta =\frac{{\epsilon }_{0}hc}{2e^2}=\frac{\pi \hslash }{c{\mu }_0{e}^2}}$ is the magnetic coupling constant for fictitious magnetic charges. ^[9]

The force of gravitational torsion field between two fictitious elementary torsion masses is:

${\displaystyle F_{\mathrm{\Omega }}=\frac{1}{4\pi {\mu }_{g0}}\cdot \frac{m_{\mathrm{\Omega }}^2}{r^2}={\beta }_g\cdot \frac{\hslash c}{r^2},}$

where ${\displaystyle {\beta }_g=\frac{{\epsilon }_{g}hc}{2m_S^2}=\frac{\pi \hslash }{c{\mu }_{g0}{m}_S^2}}$ is gravitational torsion coupling constant for gravitational torsion mass ${\displaystyle m_{\mathrm{\Omega }}}$.

In case of equality of the above forces, we shall get equality of the coupling constants for magnetic field and gravitational torsion field:

${\displaystyle \beta ={\beta }_g=\frac{1}{4\alpha },}$

from which Stoney mass ${\displaystyle m_S}$ and gravitational torsion mass could be derived:

${\displaystyle m_S=e\cdot \sqrt{\frac{{\mu }_o}{{\mu }_{g0}}}=\frac{e}{\sqrt{4\pi {\epsilon }_{0}G}}.}$

${\displaystyle m_{\mathrm{\Omega }}=q_m\cdot \sqrt{\frac{{\mu }_{g0}}{{\mu }_o}}=\frac{h\sqrt{4\pi {\epsilon }_{0}G}}{e}=\frac{h}{m_S}.}$

Instead of fictitious magnetic charge ${\displaystyle q_m=h/e}$ the single magnetic flux quantum Template:Math ^[10] has the real meaning in quantum mechanics. On the other hand at level of atoms strong gravitation operates and we must use strong gravitational constant. So, we believe that the strong gravitational torsion flux quantum there should be important:

${\displaystyle {\mathrm{\Phi }}_{\mathrm{\Gamma }}=\frac{h}{2e}\sqrt{\frac{4\pi {\epsilon }_0{G}_s{M}_e}{M_p}}=\frac{h}{2M_p}=1.98\cdot 10^{-7}}$ m²/s,

which is related to proton with its mass ${\displaystyle M_p}$ and to its velocity circulation quantum.

• Lorentz-invariant theory of gravitation
• [[../Gravitoelectromagnetism/]]
• Speed of gravitation
• [[../Maxwell-like gravitational equations/]]
• [[../Gravitational induction/]]
• Gravitational characteristic impedance of free space
• [[../Selfconsistent electromagnetic constants/]]
• [[../Velocity circulation quantum/]]
• Quantum Gravitational Resonator
• Classical electromagnetism
• Gravitational wave

Template:Reflist

• Selfconsistent gravitational constants in Russian