Spin, Planck s constant h and constant G

Spin is measured in the values of the reduced Bar .  The spin corresponding to one is a rotation of three hundred and sixty degrees.  Values that are multiples of it correspond to rotations at angles equal to one divided by the corresponding multiples of angles (for example, spin 1/2 is equal to the angle of rotation by 720°). Most likely, spin resembles the spatial spiral of Archimedes in the energy space ( 3+1+1 ) .
Let us turn to the theory of electroweak interaction .  In the theory of electroweak interaction, the photon J and the boson Z° are a superposition of two other particles - B° and W° :

Z°  = W° x cos Q_W  - B° x sin Q_W ,
J   = W° x sin Q_W  + B° x cos Q_W ,

where Q_W is the electroweak Weinberg angle .  For 2004, the best estimate of this value is
sin^2 Q_W =0.23120±0.00015 (at Q = 91.2 GeV/sec, as part of a modified minimum subtraction scheme).  In an experiment to study the asymmetry of Mellerian scattering at Q = 16 GeV/sec, the value sin^2 Q_W = 0.2397±0.00013 was found to be significantly different from the above value obtained at high energies, and it allows us to establish the dependence of the Weinberg angle on energy.   From these data, it can be seen that the Weinberg angle will have a value from 28°10' to 29°15'.

  If the Weinberg angle QW is multiplied by 2П, then the angle value is close to 180 degrees. That is, the angle of rotation of the Weinberg when rotating by 2П (360 degrees)  it will be about 180 degrees.  In order for the Weinberg angle to make a full 360 degree rotation, it is necessary to make a 4П (720 degree) rotation. The ratio of the total rotation by the Weinberg angle to 720 degrees will be 1/2 .  This ratio is typical for electrons, neutrons, and other leptons and quarks. It's their back.  For ±W and Z bosons, the Weinberg angle doubles because they have a direction of rotation in both directions relative to the isotopic spin. That is, when rotating by 2П ( 360°), the angle of rotation of the Weinberg angle will be 360°. The ratio of the total rotation by the Weinberg angle to 360° will be 1. This is their spin.

Let us now consider some interesting coincidences between the above formula, which in the theory of electroweak interaction describes the photon ; and the boson Z° as a superposition of two other particles B° and W°, and the formula for the velocity of a point that moves in a Cartesian coordinate system with a constant velocity V, directed parallel to the X axis relative to the plane, in the plane X_1 Y_1, if the plane X_1 Y_1 rotates at a constant angular velocity around the Z axis.  In this case, the velocity can be written using the formula :

 | V_o|  = (V^2 + w^2 x (V x t)^2 )^0,5

The velocity projection V on the X and Y axes will be equal :

V_x = V x cos w x t  - ( w x ( V x t  ) x sin w x t ;
V_y = V x sin w x t  + ( w x ( V x t  ) x cos w x t

The motion of the point described by these formulas is shown in Fig. 1.

It is possible to notice the coincidence of formulas for particles in a single space of electroweak interactions and formulas for the velocity of a point in a flat two-dimensional Archimedean spiral in their structural component.   That is, the photon and the Z° boson can be considered as projections on two orthogonal energy axes .   
At normal low energies, the weak and electromagnetic interactions differ from each other.  At energies greater than 100 GeV, when they combine into one electroweak interaction and the spatial energy spiral takes on the appearance of a two-dimensional Archimedean spiral, they are described by an equation similar to the equation describing the motion of the material point of the Archimedean spiral.  The dimension of the existence of particles is described by a two-dimensional energy space.   At low energies, the electroweak energy space splits into the space of electromagnetic interactions, the space of weak interactions and the space of strong interactions, and the energy space becomes three-dimensional.  The relationship between the spaces of electromagnetic, weak and strong interactions took the form of an Archimedean spatial spiral with transitions between electromagnetic, strong and weak spaces.  The strong interaction is not described by a general equation with the electroweak interaction because the strong interaction has a different character from the electroweak interaction. It has the character of a resonant interaction and appears only at low energies of particle existence.
At low energies of the energy space, a flat energy Archimedean spiral takes the form of a more general case of an energy spatial Archimedean spiral.   At the same time, it describes a ( 3+1 ) dimensional space.  Three coordinates of this space make up the energy coordinates, and one coordinate is the gravitational coordinate.
The relationship between the gravitational constant and Planck's constant h has the form :

G/h = ( 1 + L ) x 10^23 = c/(2П x M^2 ),(G x M^2)/r = (c x h)/(2П x r ), where

( 1 + L ) x 10^23 is the tangent of the angle L ( see Fig. 2 ) ;
П - is  the number of pi;
G - is the gravitational constant ;
h - is Planck's constant;
L - is a fine structure constant;
c - is the speed of light in a vacuum;
M - is Planck's mass;
m - mass;
r - is the radius of the energy spiral ( see Fig. 2 )

Thus, commensurate ratios are obtained:(G x m^2)/r is measured in N x m and
(c x h)/(2П x r) It is measured in joules.

Also, when considering the dimension of Planck's constant h, it can be seen that it corresponds to the dimension of the moment of the pulse:

h = m x v x r = cons , where

m - weight, kg
v - is the speed, m/sec
r - is the radius of rotation, m

that is, kg x m^2 x sec^-1 , that is, we can say that Planck's constant is a constant corresponding to the law of conservation of angular momentum.
 

The three energy coordinates of the plane of the electromagnetic interaction space of this spiral constitute the lowest energy level.  Each coordinate of this space represents a plane orthogonal to other coordinates - planes.  So one of these orthogonal coordinate planes corresponds to the magnetic field inductance B, the second coordinate plane corresponds to the magnetic field strength H, and the third coordinate is the electric field strength plane.  The space of electromagnetic interactions is the four-dimensional energy space closest to us.  At the same time, the transition from the four-dimensional space of existence of particles in their energy space to our three-dimensional space has characteristics that are associated with Planck's constant h and the gravitational constant G.  In addition to the space of electromagnetic interaction with the three plane coordinates mentioned above, there is also a space of strong interactions with three plane coordinates: the Baryon number plane, the Charm plane, and the Truth plane.  There is also a space of weak interactions with three coordinate planes: the Lepton Number plane, the Strangeness plane, and the Charm plane.    A spatial energy spiral with transitions between electromagnetic, strong and weak interactions is shown in Fig. 2.
 
 When you rotate 360° in this energy spiral, the properties of the space in the energy spiral change.   These are different properties of the energy Archimedean spiral and have the properties of spaces of electromagnetic, strong and weak interactions.  We can say that spin is a consequence of the transition of the properties of the four-dimensional space of existence of particles with a large number of degrees of freedom into our three-dimensional space with fewer degrees of freedom.  Let me remind you that in four-dimensional space, rotation is determined by six angular parameters and four spatial coordinates.  In three-dimensional space, rotation is determined by three angular parameters and three spatial coordinates.  Therefore, the spins of the particles have the form of spirals of the left or right direction of rotation.   When moving into three-dimensional space from the four-dimensional space of particle existence, spin has the form of a coiled Mobius filament with its rotation angle by the Weinberg angle Q_W.  The value of Planck's constant h corresponds to the step of the last turn of the spatial Archimedean spiral "a" in the horizontal direction when exiting four-dimensional space into our three-dimensional space.    The value of the gravitational constant G corresponds to the step of the last turn of the spatial Archimedean spiral in the vertical direction when exiting four-dimensional space into our three-dimensional space.  ( Shown in Figure 2 ).

Due to the properties of the energetic Archimedean spiral described above, ±W bosons and Z bosons are the result of the decay of unstable particles of a higher energy level to particles of a lower energy level.  In this case, energy is released in the form of ± W boson or Z boson .    In this case, the energy transition occurs along a turn of the energy Archimedean spiral, and as a result, ±W bosons decay into an electron and an antineutrino or a positron and a neutrino at the lowest energy level of ± W boson.  At the lowest energy level, the Z boson decays into quark–antiquark forming mesons.    ± W bosons correspond to the transition along the spiral of the energy spiral, when the sum of the turns of the spiral direction ( left or right spiral )   plus the direction of rotation at the Weinberg angle Q_W have one direction .  In this case, the left direction corresponds to the -W boson, and the right direction corresponds to the +W boson.  The transition along the energy turn of the Archimedean spiral, when the sum of the turns of the spiral direction ( left or right spiral) plus the direction of rotation by the Weinberg angle have a different direction, leads to the formation of a Z-boson, the electric charge of which is zero.