THE ELECTROMAGNETIC ENERGY
AND THE SPEED
The speed c
of the light results from the equations of Maxwell, that include
phenomena (μ_{ο}, ε_{ο},
z_{o}) where belong in the electromagnetism. In the course of time, the electromagnetism and the motion of
electron constituted a fascinating, precious and inexhaustible field for research. A big piece of science, technology and
particularly the physics are connected with the speed of the light c and its relation with the electromagnetism. A creative
brain can't to don't observe and don't succumb in the temptation to correlate some known types of physics for the phenomena
that belong in the electromagnetism, with types for phenomena that describe the simple motions of the big bodies.
Magnetic
Penetrability
of free space μ_{ο}
= 4π
x 10^{7}
Η/m = 12,566368
x10^{7}
Henry /m
Dielectric Constant
of free space
ε_{ο}
= 1/36π 10^{9}
= 8,854
x 10^{12}
Farad /m
Characteristic
resistance of free space
z_{o} =
√(μ_{ο}/ε_{ο}
)
= μ_{ο} c ~ 377 Ohm
The speed of the
light in the free space is given from the relation
c_{ο} =
1/√(μ_{ο} ε_{ο})
Henry
=
Volt sec / Ampere = Ω sec (Resistance
V/A)
Farad
=
Ampere sec / Volt = 1/Ω sec =
Ω^{1}
sec (Conductance
A/V)
Henry
x
Farad
= sec^{2}
Ohm
=
Volt / Ampere
c^{2} = 1
/ μο
εο
→ cο = 1 /√(μο
εο
)
√(μο
/ εο
)
= Ω = 1,2 x 10^{2}
π = 120 π
From the relations
c^{2}
= 1/μ_{ο} ε_{ο}
and
c = 1/√(μ_{ο}
ε_{ο}) we find :
μο
= 1 / c^{2}
εο and
εο
= 1 / c^{2}
μο
√(μο
/ εο
)
= √1,419254
x10^{5}
=3,767
x10^{2}
Ω =
μο
c =
1,2
x10^{2}
π =120π
μο
c
= 1/c εο
= zo
μο
c = RESISTANCE
 εο
c = CONDUCTANCE
(H /m)
m/s = H / sec
 (F/m) m/s = F/sec
Henry = Volt x sec / Ampere = Ω
x
sec (Resistance R=V/I)
Farad = Ampere x sec / Volt = 1/Ω
x
sec = Ω^{1} sec (Conductance S=I/V)
1 Farad
= 1 Coulomb / 1 Volt (C= Q/V)
1 Volt =
1 Joule / 1 Coulomb (V= P/I = IR)
1 Ampere
= 1 Coulomb / sec (I= Q/t)
1
Coulomb = 1 Ampere x sec (Q= I t)
1 Ohm
= 1
Volt / 1
Ampere (kg m^{2}
s^{3}
A^{2})

The magnetic
penetrability μ_{ο} and the dielectric constant ε_{ο}
are from the first phenomena which are presented in our visible world by the motion in to space and which are connected with
particular phenomena of microscopic space and exclusively in the structure of matter. The phenomenon of solid mass is
presented by fast and alternating fluctuations in the transfer of wave energy, while in our visible world the mass is
appeared like a perfectly separate and selfexistent phenomenon. Similar, the phenomena of electricity and magnetic field
are presented, so as if they do not have equivalence with the phenomena of motion in the material world. A potential
comprehension of these phenomena (that mathematically receive the values of μ_{ο} and ε_{ο})
with equivalent terms from the motion of bodies, it will constitute a gate for the comprehension and for the
crosscorrelation of many other phenomena in the structure of matter and about the relation between of natural forces.
It has become more than a suspicion, that certain from the phenomena that are
described in the physics as irrelevantly and separately are intermediary situations or particular cases of most known
phenomena, particularly of the motion. Between these phenomena, we expect that is the dielectric constant of the free space εο
= 8,8542 x10^{12} F/m and the magnetic penetrability
μο = 12,56636
x10^{7} H /m , from that results the biggest speed of
electromagnetic waves (c = 1 / √ εο
μο ).
μ_{ο} = 4π x 10^{7} Η/m = 12,566368 x10^{7} Henry
/m
ε_{ο} = 1/36π 10^{9} = 8,854 x 10^{12} Fd /m
G = 6,6725 x10^{11}  c = 2,997924 x10^{8}
m/s  c G ≈ 0,02
z_{ο} = 120π = 376,9 Ω = √(μ_{ο} / ε_{ο}) = √1,42 x10^{5}
√μ_{ο}
= 1,1209977 x10^{3}
√ε_{ο} = 2,9755671 x10^{6}
►
The
frequency
fmax
= 0,452444 x10^{42}
Hz
is result from the magnetic penetrability
μ_{ο}
=12,56636 x10^{7}
Henry
/m
with the
dielectric constant ε_{ο}=
8,854 x 10^{12}
Farad
/m of the free space, when
we consider that the Planck's constant h
coincides with a fundamental length λmin
= 6,62606 x10^{34}
m
and applying the relation V_{c}
=1/ √μ_{ο} ε_{ο}
and the fundamental relation for the coordination in
electrotechnics
T= 2π√L·C.
In the
type
T= 2π√L·C
we consider the length λmin
= hbar
2π :
L = μ_{ο}
λ_{min}
= 83,265508 x10^{41
}Henry
C = ε_{ο}
λ_{min}
= 58,667135 x 10^{46} Farad
T^{2} = (83,26550 x10^{41}
) (58,66713 x10^{46}^{ }
)= 4884,95 x10^{87}
(Henry x Farad = sec^{2}
)
T = √4,88495
x10^{84}
= 2,2102 x 10^{42}
sec
f = 1/2,2102 x10^{42}
= 0,45244 x10^{42}
Hz
Henry =
z_{o} sec → sec =
Henry/z_{o}
Really
83,265508 x10^{41}
/ 376,9 = 2,21 x10^{42}
Farad = sec /z_{o} →
z_{o} =sec /Farad → sec=Farad x z_{o}
