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4.3
Unification of the gravitation force with the strong force
From the CTH, there result some
interesting
relations between the strong force and the gravitation force which
could
have a fundamental importance for the unification of all natural
forces.
According to the SUSY ( super symmetry theory), all natural forces were
identical, i. e. the strong nuclear force and the gravitation force,
too,
were equally large at the Planck time
(tPL»10
- 43 s)
As Fig. 5 shows, the universe had,
at the Planck time, quite exactly, the size of an elementary particle
(R
PL»
re
»10
-15
m). This space extension, also called “elementary length re"plays a dominant role in the total particles
physics(Yukawa radius, Compton
wavelength of the proton, classical electron radius) [28], p. 628.
The elementary length re»
10-15 m , by the way, also results
when
we multiply the light speed, viewed from the now time perspective at
the
Planck time cPL = 3 ·10 28
m/s (see Fig. 5), by the Planck time, also related to the now
time.
(re = cPL
· t PL
= 3 · 10 28
·
5 · 10 - 44 = 1.5 · 10 -15
m)
Furthermore, it is surprising,
the gravitation constant and, with it, the gravitation force at the
Planck
time was by the factor
10 41
larger than today (Fig. 5). That means, according to the CTH, the
gravitation
force and the strong nuclear force were equally large at the Planck
time,
exactly as demanded by the SUSY! This relation becomes all the more
exciting
if we link both forces to their respective radius of action.
The strong nuclear force Fs
has a radius of action of re
»
10
-15 m (Yukawa radius). Its force is, as mentioned, by the
factor
10 41
stronger than that of today’s gravitation force.
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