Physics/Essays/Fedosin/Selfconsistent electromagnetic constants

Selfconsistent electromagnetic constants is the full set of fundamental constants of classical electromagnetism that are selfconsistent and determine the external definitions of different physical quantities (and its fundamental dimensions), and therefore – the resulting set of the Maxwell's equations. The constants are confirmed by the fact that they work in any systems of measurement and are part of vacuum constants.

The primary set of electromagnetic constants is:

1. the first electromagnetic constant (${\displaystyle c}$), which is the speed of light or speed of the electromagnetic waves in free space; ${\displaystyle c=299792458}$ metres per second.^[1]
2. the second electromagnetic constant, which is the impedance of free space ${\displaystyle Z_0=376.73031...}$ Ω.^[2]

The secondary set of electromagnetic constants is:

1. the electric constant or vacuum permittivity:

${\displaystyle {\epsilon }_0=\{\begin{array}{cc}\frac{10^7}{4\pi c^2}=8.85418782\cdot 10^{-12}\text{F/m},& \text{(SI units)}\\ \frac{1}{4\pi },& \text{(Cgs units)}\end{array}}$

2. the magnetic constant or vacuum permeability:

${\displaystyle {\mu }_0=\{\begin{array}{cc}4\pi \cdot 10^{-7}\text{H/m},\text{Wb/(A m)},\frac{\text{N}}{A^2},& \text{(SI units)}\\ \frac{4\pi }{c^2},& \text{(Cgs units)}\end{array}}$

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

${\displaystyle \frac{1}{\sqrt{{\epsilon }_0{\mu }_0}}=c,}$

${\displaystyle \sqrt{\frac{{\mu }_0}{{\epsilon }_0}}=\{\begin{array}{cc}{Z}_0=\frac{1}{c{\epsilon }_0}=c{\mu }_0=c\cdot 4\pi \cdot 10^{-7}\mathrm{\Omega },& \text{(SI units)}\\ Z_0^{Cgs}=\frac{4\pi }{c}=4.19169\cdot 10^{-10}\text{s/cm},& \text{(Cgs units)}\end{array}}$

Note that in the Cgs units ${\displaystyle {\epsilon }_0,{\mu }_0}$ and ${\displaystyle Z_0}$ are in the "latent form" and therefore are not defined evidently, but they are the same as defined above. Furthermore, the values of impedance of free space in the SI units and Cgs units are connected by the following relation: ^[3]

${\displaystyle Z_0^{Cgs}=4\pi {\epsilon }_0\cdot Z_0^{SI}}$

The electromagnetic constants may be found in many equations and also connect with other constants. Introducing the Planck constant ${\displaystyle h}$ and the elementary charge ${\displaystyle e}$ we find:

the fine structure constant ${\displaystyle \alpha =\frac{e^2}{2{\epsilon }_{0}hc}}$,

the von Klitzing constant ${\displaystyle R_K=\frac{h}{e^2}}$,

the impedance of free space ${\displaystyle Z_0=2\alpha R_K}$.

Another example is the strong gravitational constant ${\displaystyle \mathrm{\Gamma }=\frac{e^2}{4\pi {\epsilon }_0{m}_p{m}_e}}$,

where ${\displaystyle m_p}$ – the mass of proton, ${\displaystyle m_e}$ – the mass of electron.

There is the delicate problem of electromagnetic constants in the classical electromagnetism up to now. Actually, in the CGS units only two constants: ${\displaystyle c}$ (speed of light) and ${\displaystyle 4\pi }$ are used,^[4] but in the SI units there are four constants: ${\displaystyle {\epsilon }_0}$ (electric constant), ${\displaystyle {\mu }_0}$ (electric constant), ${\displaystyle c}$ ( speed of light) and ${\displaystyle Z_0}$ (impedance of free space). Furthermore, the impedance of free space was introduced by Stratton only in the 1941,^[5] which are widely used in the applied physics. But the second set (${\displaystyle {\epsilon }_0}$ and ${\displaystyle {\mu }_0}$) is mostly considered as "artificial" ones, that have no physical meaning,^[6] and used only for the sake of dimension consistency of the physical quantities (such as in electrostatic induction with ${\displaystyle {\epsilon }_0}$, and in electromagnetic induction with ${\displaystyle {\mu }_0}$).

However, with the discovery of the quantum Hall effect by von Klitzing (1981)^[7] the theorists paid serious attention to the physical essence of resistance (or impedance), which is due to the charges or fluxes. Actually, Yakymakha (1989)^[8] first introduced the magnetic coupling constant, defined through the magnetic monopole,^[9] and in the 1994^[10] for the first time the impedance of free space was observed in the quantum 2D-electron system at the silicon- dioxide interface of the serial MOSFETs. Further, Tsu and Datta (2003)^[11][12] considered for the first time the new interpretation of the wave function in the Schrodinger equation, defined through the impedance of free space. Increasing attention to the impedance of free space as part of the general problem of the characteristic impedance was shown by Zel’dovich (2008).^[13]

The main conception of the Cgs units is defined on the primary nature of electromagnetic fields. So, here we have the same dimensions for electric and magnetic fields:

${\displaystyle [E]=[D]=[H]=[B]=L^{-1/2}{M}^{1/2}{T}^{-1}}$

Contrary to the Cgs units, the SI units have different dimensions of the electromagnetic fields (in vacuum):

${\displaystyle D={\epsilon }_{0}E}$

${\displaystyle B={\mu }_{0}H,}$

which is based on the different dimensions of electric and magnetic charges:

${\displaystyle [e{]}^{SI}=}$Coulomb,

${\displaystyle [q_m{]}^{SI}=}$J/A.

In the general case, when the space is filled by matter, these definitions are changed:

${\displaystyle D={\epsilon }_0{\epsilon }_{r}E}$

${\displaystyle B={\mu }_0{\mu }_{r}H,}$

where ${\displaystyle {\epsilon }_r}$ is the relative permittivity, and ${\displaystyle {\mu }_r}$ is the relative permeability.

In the electromagnetic wave propagation process we have the following relationships between electric and magnetic fields:

${\displaystyle \sqrt{{\mu }_r}𝐇=\sqrt{{\epsilon }_r}𝐄}$ (Cgs units)

${\displaystyle \sqrt{{\mu }_0{\mu }_r}𝐇=\sqrt{{\epsilon }_0{\epsilon }_r}𝐄.}$ (SI units)

Note that, in the Cgs units it is hard to define the wave impedance, and therefore it is often said that there are no any wave impedance.^[14] But using the generalized definition of the wave impedance in the form:

${\displaystyle Z=\sqrt{\frac{{\mu }_0{\mu }_r}{{\epsilon }_0{\epsilon }_r}},Z^{Cgs}=\frac{4\pi }{c}\sqrt{\frac{{\mu }_r}{{\epsilon }_r}},}$

we can rewrite the above equations for the wave in the general form:

${\displaystyle 𝐄=\frac{Z^{Cgs}}{Z_0^{Cgs}}𝐇}$ (Cgs units)

${\displaystyle 𝐄=Z𝐇,}$ (SI units)

where the fact of the same dimensions of electric and magnetic fields in the Cgs units is considered.

The same problem of dimensions equality is presented in the Cgs units for reactive parameters. Actually, the standard capacitance is defined as:

${\displaystyle C=\frac{Q}{V},}$

where the dimension of electric charge in Cgs units is ${\displaystyle [Q]=L^{3/2}{M}^{1/2}{T}^{-1}}$, and the dimension of electric voltage is ${\displaystyle [V]=L^{1/2}{M}^{1/2}{T}^{-1}}$ . So, capacitance in the Cgs units has dimension of the length ${\displaystyle [C]=L.}$ Furthermore, the standard inductance is defined as:

${\displaystyle L=c\frac{\mathrm{\Phi }}{I},}$

where the dimension of magnetic flux is ${\displaystyle [\mathrm{\Phi }]=L^{3/2}{M}^{1/2}{T}^{-1}}$, and the dimension of electric current in the Cgs units is ${\displaystyle [I]=L^{3/2}{M}^{1/2}{T}^{-2}}$. So, inductance has the same dimension of the length ${\displaystyle [L]=L}$.

The main problem in the Cgs units is the LC circuit resonance parameters. Actually, the natural values of the resonance frequency (${\displaystyle {\omega }_R}$) and characteristic impedance (${\displaystyle Z_R}$) in a lossless line are working well in the SI units only:

${\displaystyle {\omega }_R=\frac{1}{\sqrt{LC}}}$

${\displaystyle Z_R=\sqrt{\frac{L}{C}}.}$

But in the Cgs units characteristic impedance is dimensionless and angular frequency is reverse square of the length. Therefore, theoretics which prefer Cgs units, when considering LC circuit use the SI units.^[4]

So, redefinition of them through the electromagnetic constants is needed:

${\displaystyle {\omega }_R=\frac{c}{\sqrt{LC}}}$

${\displaystyle Z_R=Z_0^{Cgs}\sqrt{\frac{L}{C}}.}$

Considering the following relationships between electromagnetic constants:

${\displaystyle {\epsilon }_0=\frac{1}{c{Z}_0},Z_0^{Cgs}=\frac{4\pi }{c},}$

${\displaystyle {\mu }_0=\frac{Z_0}{c}.}$

In the Cgs units, macroscopic Maxwell's equations can be rewritten in the normalized form:

${\displaystyle \mathrm{\nabla }\times 𝐇=Z_0^{Cgs}{𝐉}_f+\frac{1}{c}\frac{\partial 𝐃}{\partial t}}$

${\displaystyle \mathrm{\nabla }\times 𝐄=-\frac{1}{c}\frac{\partial 𝐁}{\partial t}}$

${\displaystyle \mathrm{\nabla }\cdot 𝐁=0}$

${\displaystyle \mathrm{\nabla }\cdot 𝐃=c{Z}_0^{Cgs}{\rho }_f.}$

where ${\displaystyle {\rho }_f}$ is the free electric charge 3D-density, and ${\displaystyle J_f}$ is the current density of free charges.

Note that in this normalized form there are only the primary electromagnetic constants included (without ${\displaystyle 4\pi }$).

The electric Coulomb's Law for two elementary charges ${\displaystyle e}$ is defined as:

${\displaystyle F=\frac{1}{4\pi {\epsilon }_0}\cdot \frac{e^2}{r^2}.}$

In the Cgs units we have:

${\displaystyle F^{Cgs}=\frac{e^2}{r^2}.}$

The magnetic force between two fictitious elementary magnetic charges can be defined as follows:

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

where ${\displaystyle q_m=\frac{h}{e}}$ is the magnetic charge. The same in the Cgs units is:

${\displaystyle F_m^{Cgs}=\frac{g_0^2}{r^2},}$

where

${\displaystyle g_0=\frac{q_m}{Z_0^{Cgs}}=\frac{\hslash c}{2e}}$

is the normalized magnetic charge (or Dirac's monopole in the Cgs units). ^[15][16] Furthermore, electric and magnetic charges in the Cgs units have the same dimensions:

${\displaystyle [g_0]=[e]=L^{3/2}{M}^{1/2}{T}^{-1}}$

and could be compared:

${\displaystyle \frac{g_0}{e}=\frac{\hslash c}{2e^2}=\frac{1}{2{\alpha }^{Cgs}}=\sqrt{\frac{{\beta }^{Cgs}}{{\alpha }^{Cgs}}}=2{\beta }^{Cgs},}$

where ${\displaystyle {\alpha }^{Cgs}=\frac{e^2}{\hslash c}}$ is the electric fine structure constant in the Cgs units, and ${\displaystyle {\beta }^{Cgs}=\frac{1}{4{\alpha }^{Cgs}}=\frac{\hslash c}{4e^2}}$ is the magnetic coupling constant in the Cgs units for the fictitious magnetic charges.

Thus, the relationship between Coulomb forces will be:

${\displaystyle \frac{F_m^{Cgs}}{F^{Cgs}}=\frac{g_0^2}{e^2}=\frac{1}{4({\alpha }^{Cgs}{)}^2}=\frac{{\beta }^{Cgs}}{{\alpha }^{Cgs}}=4({\beta }^{Cgs}{)}^2}$

which is the same as in the SI units:

${\displaystyle \frac{F_m}{F}=\frac{{\epsilon }_0{q}_m^2}{{\mu }_0{e}^2}=\frac{1}{4{\alpha }^2}=\frac{\beta }{\alpha }=4{\beta }^2,}$

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

In consistence to the Quantum Electromagnetic Resonator approach, the charge multiplication (electric and magnetic) should be equal to the quant of action:

${\displaystyle e\cdot g_0=h,}$

where ${\displaystyle e}$ is the electric charge, ${\displaystyle g_0}$ is the magnetic charge, and ${\displaystyle h}$ is the Planck constant (or the quant of action).

There are no problems in the SI units, where ${\displaystyle g_0=q_m=h/e}$, but in the Cgs units we have the same dimensions of the charges:

${\displaystyle [e]=[g_0].}$

Therefore, to restore the self consistence of the Cgs units we should to consider the second electromagnetic constant ${\displaystyle Z_0^{Cgs}}$:

${\displaystyle Z_0^{Cgs}\cdot (e{g}_0)=h,}$

which is an analog of the uncertainty principle in the quantum mechanics.

Simple theory presented by Laughlin^[17] to explain QHE ^[7] used the following definition of the adiabatic strip current in the Cgs units:

${\displaystyle I=c\cdot \frac{\partial U}{\partial \varphi }=\frac{c}{L_l}\frac{\partial U}{\partial A},}$

where ${\displaystyle \varphi =L_{l}A}$ is the magnetic flux, ${\displaystyle A}$ is the vector potential, and ${\displaystyle L_l}$ is the strip length. Using the following changes of total energy ${\displaystyle U}$ and magnetic flux between Landau levels:

${\displaystyle \mathrm{\Delta }U=(n+\frac{1}{2})eV}$

${\displaystyle \mathrm{\Delta }\varphi =\frac{hc}{e}={\varphi }_l,}$

we obtain the following current:

${\displaystyle I=c\cdot \frac{\mathrm{\Delta }U}{\mathrm{\Delta }\varphi }=(n+\frac{1}{2})\frac{e^2}{h}V,}$

where ${\displaystyle n=1,2,3,...}$, and ${\displaystyle V}$ is effective potential of the level. Note that, this magnetic flux quantum ${\displaystyle {\varphi }_l}$ is different from Dirac monopole:

${\displaystyle {\varphi }_l=4\pi g_0=\frac{hc}{e}.}$

Let us consider ${\displaystyle C_p}$ and ${\displaystyle L_p}$ as quantum capacitance and inductance of free photon in the SI units. We shall suppose that characteristic impedance of photon equals to the impedance of free space:

${\displaystyle Z_p=Z_o=\sqrt{\frac{L_p}{C_p}}=\sqrt{\frac{{\mu }_0}{{\epsilon }_0}}.}$

Then the resonance frequency will be:

${\displaystyle {\omega }_p=\frac{1}{\sqrt{L_p{C}_p}}=2\pi {\nu }_p=\frac{2\pi c}{{\lambda }_p},}$

where ${\displaystyle {\lambda }_p}$ is wavelength of photon. The solution of these two equations will be:

${\displaystyle C_p=\frac{{\lambda }_p}{2\pi c{Z}_0}=\frac{{\lambda }_p{\epsilon }_0}{2\pi }=\frac{{\epsilon }_0}{2{\lambda }_p}{S}_p}$

${\displaystyle L_p=\frac{{\lambda }_p{Z}_0}{2\pi c}=\frac{{\lambda }_p{\mu }_0}{2\pi }=\frac{{\mu }_0}{2{\lambda }_p}{S}_p,}$

where ${\displaystyle S_p=4\pi r_p^2=\frac{{\lambda }_p^2}{\pi }}$ and ${\displaystyle r_p=\frac{{\lambda }_p}{2\pi }}$ is the photon intrinsic radius.

• International System of Units
• Centimetre–gram–second system of units
• Classical electromagnetism
• Quantum Electromagnetic Resonator
• Selfconsistent gravitational constants

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