Constantinos G. Vayenas^1,2*, Dionysios Tsousis^1,3, Dimitrios Grigoriou¹, Konstantinos Parisis⁴, Elias C. Aifantis^4,5,6*
1University of Patras, Patras, Greece.
²Academy of Athens, Athens, Greece.
³Stanford University, Stanford, USA.
⁴Aristotle University of Thessaloniki, Thessaloniki, Greece.
⁵Michigan Technological Institute, Houghton, USA.
⁶Friedrich-Alexander University, Erlangen-Nürnberg, Germany.
DOI: 10.4236/jamp.2022.109187   PDF    HTML   XML   83 Downloads   600 Views   Citations

Abstract

The present article is a continuation of a recently published paper [1] in which we have modeled the composition and structure of neutrons and other hadrons using the Rotating Lepton Model (RLM) which is a Bohr type model employing the relativistic gravitational attraction between three ultrafast rotating neutrinos as the centripetal force. The RLM accounts for special relativity and also for the De Broglie equation of quantum mechanics. In this way this force was shown to reach the value of the Strong Force while the values of the masses of the rotating relativistic neutrinos reach those of quarks. Masses computed for twelve hadrons and bosons are in very close (~2%) agreement with the experimental values. Here we use the same RLM approach to describe the composition and structure and to compute the masses of Pions and Kaons which are important zero spin mesons. Contrary to hadrons and bosons which have been found via the RLM to comprise the heaviest neutrino eigenmass m₃, in the case of mesons the intermediate neutrino mass eigenstate m₂ is found to play the dominant role. This can explain why the lowest masses of mesons are generally smaller than those of hadrons and bosons. Thus in the case of Pions it is found that they comprise three rotating m₂ mass eigenstate neutrinos and the computed mass of 136.6 MeV/c² is in good agreement with the experimental value of 134.977 MeV/c². The Kaon structure is found to consist of six m₂ mass eigenstate neutrinos arranged in two parallel pion-type rotating triads. The computed Kaon mass differs less that 2% from the experimental K^± and K° values of 493.677 MeV/c² and 497.648 MeV/c² respectively. This, in conjunction with the experimentally observed decay products of the Kaons, provides strong support for the proposed K structure.

Keywords

Pions and Kaons-Structure and Masses, Gravitational Bohr-de Broglie-Newton-Einstein Type Models, Rotating Lepton Model (RLM), Hadronization, Neutrino Masses, Special Relativity, Gravitational Force, Quantum Mechanics

Share and Cite:

1. Introduction

The Standard Model (SM) of particle physics has long provided a basis for understanding the fundamental structure of all observable matter in our Universe. Among the indivisable particles it describes are quarks and leptons, which include electrons, positrons and neutrinos. The SM also describes four forces: gravity which plays a very limited role, electromagnetism which regulates interactions between charged particles via photons, the Strong Force which acts between quarks via gluons and the Weak Force which involves exchanges of W and Z boson and plays an important role in radioactive decay. So far the SM has provided an excellent basis for researchers to explain their experimental results [2] [3]. In recent years, however, there is increasing evidence that the SM in its current form is not complete. In fact, the SM does not seem to be compatible with special or general relativity and, in addition, it assumes that neutrinos are massless, despite of subsequently established experimental evidence that neutrinos possess mass and play a paramount dominant role in our Universe [4] [5] [6] [7] [8]. This lack of completeness has led to developing the rotating lepton model (RLM) which is a Bohr-type rotating lepton model [9], combining gravity, special [10] [11] or general relativity [12] and quantum mechanics [13] in a simple manner [1] [14] - [20].

Following the general observation [2] [3] that all composite particles eventually decay to only up to five lepton types (electrons e⁻, positrons e⁺ and the three neutrinos) the RLM considers these particles as the only truly undivisable, thus fundamental, elementary particles which can synthesize all composite particles [9] [20] [12] - [17]. The RLM also utilizes the three neutrino eigenmass values to show that, due to their very small rest masses m_o, neutrino masses can reach the Planck mass values at modest (up to 313 MeV) energies.

The latter implies that gravitational forces between ultrarelativistic neutrinos, at a distance d, can easily reach the value, $\hslash c/d^2$, of the Strong Nuclear Force which is the strongest force for creating composite particles. Here $\hslash$ is the Planck constant and c is the speed of light.

Consequently the RLM utilizes only two forces, i.e. gravity and electromagnetism and shows that matter is created via the rotation of neutrino triads in circular orbits with rotational speeds near the speed of light c, and corresponding Lorentz factor $\gamma \left(={\left(1-v^2/c^2\right)}^{-1/2}\right)$ values up to 10¹⁰. In this way it turns out that the new mass created is $\left(\gamma -1\right)m_o{c}^2$. As an example, as shown in the next section, three rotating neutrinos, of rest mass 0.0437 eV/c² each, form a rotating triad with a Lorentz factor $\gamma$ equal to 7.163 × 10⁹. The mass of the composite particle formed is $3\gamma m_o$, i.e. 939.565 MeV/c² which is the rest mass of a neutron. The importance, simplicity and effectiveness of the RLM has been analyzed and discussed recently in Research Features [20].

2. Rotating Lepton Model of the Neutron, Muon and Pion

2.1. Neutron

Within the RLM approach the neutron is modeled as a rotating relativistic neutrino triad of the heaviest neutrino mass eigenstate m₃ (Figure 1 and Figure 2). According to Special Relativity the relativistic mass, m_r, of a neutrino is given by $\gamma m_o$ and its inertial longitudinal mass is given by

$m_i={\gamma }^3{m}_o$ (1)

where m_o is the rest mass of the neutrino and $\gamma$ is the Lorentz factor

$\gamma ={\left(1-v^2/c^2\right)}^{-1/2}$ (2)

In instantaneous reference frames, the above Equation (1), derived initially for linear motions [10] [11], remains valid for arbitrary motion [11] [14]. Therefore, using the equivalence principle, the gravitational mass, m_g, of all particles equals their inertial mass, m_i, thus

$m_g={\gamma }^3{m}_o$ (3)

Using the definition of the gravitational mass, m_g, which is the mass value entering Newton’s universal gravitational law, i.e.

$m_g^2=\frac{F{d}^2}{G}$ (4)

We obtain the following expression for the gravitational force F

$F=\frac{G{m}_o^2{\gamma }^6}{d^2}$ (5)

where G (=6.673 × 10⁻¹¹ m³∙kg⁻¹∙s⁻²) denotes the usual gravitational constant. For circular motion of three m₃ mass neutrinos rotating along a circle of radius r, it follows that F is given by

$F=\frac{G{m}_3^2{\gamma }^6}{3^{1/2}{r}^2}$ (6)

and therefore the equation of motion of each rotating particle is

$\gamma m_3{v}^2/r=\frac{G{m}_3^2{\gamma }^6}{3^{1/2}{r}^2}$ (7)

which in turn, yields

$r=\frac{G{m}_3}{3^{1/2}{c}^2}{\gamma }^5\left(\frac{{\gamma }^2}{{\gamma }^2-1}\right)$ (8)

Solving Equation (8) coupled with the de Broglie quantum mechanics equation, i.e. with

$\gamma m_{o}vr=\hslash$ (9)

accounting for the number (three) of quarks in a neutron [2] and denoting by $m_n$ the neutron mass, it follows from energy conservation (i.e. from $m_n{c}^2=3\gamma m_o{c}^2$ ) that $m_n=3\gamma m_o$ and thus

$r=3\hslash /m_{n}c;m_n=3^{13/12}{\left(m_{Pl}{m}_o^2\right)}^{1/3};m_o=m_3=\frac{{\left(m_n/3\right)}^{3/2}}{3^{1/8}{m}_{Pl}^{1/2}}$ (10)

Substituting for the neutron mass $m_n=939.565\text{MeV}/{\text{c}}^2$ and for the Planck mass $m_{Pl}=1.221\times {10}^{28}\text{eV}/{\text{c}}^2$, one obtains $m_o=0.0437\text{eV}/{\text{c}}^2$ and thus, $\gamma \left(=m_n/3m_o\right)=7.163\times {10}^9$. The so computed relativistic mass $\gamma m_o$ value is of the order of quark masses (313 MeV/c²) and the corresponding rest mass m_o value (0.04372 eV/c²) is in surprisingly good agreement with the heaviest neutrino mass m₃, as shown in Figure 1. Since this mass differs less than 2% from the mass, m₃, of the neutrino produced in the W^± decay [18] it follows that the W^± boson comprises, similarly to neutrons and protons, the heaviest mass neutrinos ${\nu }_3$ (Figure 1).

2.2. Muons

The algebraic expressions for the masses m₁, m₂ and m₃, also shown and compared in Figure 1 with the Superkamiokande measurements, are obtained by modeling the muon structure ( ${\mu }^{\pm }$ ) which is known to comprise an e^±, a ${\bar{\nu }}_e$ and a ${\nu }_{\mu }$ [2] [3]. Thus one considers two gravitating neutrinos, ${\nu }_1$ and ${\nu }_3$, of masses m₁ and m₃, respectively and, similarly to Equation (7), we have

${\gamma }_1{m}_1{v}_1^2/r=\frac{G{m}_1{m}_3{\gamma }_1^3{\gamma }_3^3}{\sqrt{3}{r}^2}$ (11)

${\gamma }_3{m}_3{v}_3^2/r=\frac{G{m}_1{m}_3{\gamma }_1^3{\gamma }_3^3}{\sqrt{3}{r}^2}$ (12)

Upon multiplying by parts, taking the square root, considering the limit $v_1\mathrm{,}{v}_3\to c$

and defining ${\gamma }_{13}={\left({\gamma }_1{\gamma }_3\right)}^{1/2}$ and $m_{13}={\left(m_1{m}_3\right)}^{1/2}$ one obtains

${\gamma }_{13}{m}_{13}{c}^2/r=G{m}_{13}^2{\gamma }_{13}^6/4r^2$ (13)

Furthermore, by multiplying by parts the two de Broglie wavelength expressions as in Equation (9), we obtain

${\gamma }_{13}{m}_{13}cr=\hslash$ (14)

From Equations (13) and (14) it follows

${\gamma }_{13}^6=\frac{4\hslash c}{G{m}_{13}^2};{\gamma }_{13}=2^{1/3}{\left(\frac{m_{Pl}}{m_{13}}\right)}^{1/3}$ (15)

where $m_{Pl}={\left(\hslash c/G\right)}^{1/2}$. Consequently, the muon mass is computed from

$m_{\mu }={\gamma }_{13}{m}_{13}=2^{1/3}{\left(m_{Pl}{m}_{13}^2\right)}^{1/3}={\left(2m_{Pl}{m}_1{m}_3\right)}^{1/3}$ (16)

and, therefore, using the experimental muon mass, $m_{\mu }=105.66\text{MeV}/{\text{c}}^2$ and the m₃ mass eigenstate value of 0.0437 eV/c² [14] [15] [17] [18], we obtain

$m_1=\frac{m_{\mu }^3}{2m_{Pl}{m}_3}=0.001105\text{eV}/{\text{c}}^2$ (17)

Interestingly the same result for the muon mass obtained from Equation (16) can also be reached by considering two rotating neutrinos, each with rest mass m₂. In this case, similarly to Equation (7), we have

${\gamma }_2{m}_2{v}^2/r=\frac{G{m}_2^2{\gamma }_2^6}{4r^2};{\gamma }_2{m}_{2}vr=\hslash$ (18)

resulting to

$4\hslash c=G{m}_2^2{\gamma }_2^6;{\gamma }_2=2^{1/3}{\left(\frac{\hslash c}{G{m}_2^2}\right)}^{1/6}$ (19)

and, therefore, to

$m_{\mu }={\gamma }_2{m}_2={\left(2m_{Pl}{m}_2^2\right)}^{1/3}=105.66\text{MeV}/{\text{c}}^2$ (20)

Then, from Equations (16) and (20) it follows that

$m_2={\left(m_1{m}_3\right)}^{1/2}=0.00695\text{eV}/{\text{c}}^2$ (21)

The above equation suggests that two neutrinos, of masses m₁ and m₃ each, can hybridize to form two neutrinos with equal masses $m_2={\left(m_3{m}_1\right)}^{1/2}$. The occurence of neutrino hybridization can be attributed to the need of synchronization when two neutrinos of different initial masses are caught on the same circular orbit in the process of forming a bound rotational state [14] [17] [18]. The phenomenon of hybridization is quite common in chemistry [21]. The phenomenon of neutrino hybridization may be related to the very important phenomenon of neutrino oscillations [4] [5] [6] [7] [8] [22].

2.3. Pions

Interestingly, the same m₁ mass value obtain in Equation (17) can be computed by modeling the structure of the pion, which is a meson, comprising (Figure 2) three rotating neutrinos [2] [3] which, as shown by the RLM, form a rotating triad. The analytical computation of the pion mass is shown below.

We consider three rotating neutrinos on a circle of radius r, two of which have the mass m₁ and the third with a mass m₃ as shown in Figure 2(c) and Figure 3.

The gravitational forces between the three rotating particles are shown in Figure 3, i.e.

$F_{11}=\frac{G{m}_1^2{\gamma }_1^6}{4r^2{\sin }^2\phi };F_{13}=F_{23}=\frac{G{m}_1{m}_3{\gamma }_1^3{\gamma }_3^3}{r^2{\sin }^2\phi }{\sin }^2\left(\phi /2\right)$ (22)

and thus

$\frac{F_{11}}{F_{13}}=\frac{m_1{\gamma }_1^3}{4m_3{\gamma }_3^3{\sin }^2\left(\phi /2\right)}$ (23)

From Figure 3 it also follows

$\alpha =2r\sin \phi$ (24)

$\frac{\alpha }{\sin \phi }=\frac{\beta }{\sin \left(90-\phi /2\right)}$ (25)

Thus,

$\beta =\alpha \frac{\cos \left(\phi /2\right)}{\sin \phi }=\frac{\alpha }{2\sin \left(\phi /2\right)}$ (26)

and from Equation (24)

$\beta =r\frac{\sin \phi }{\sin \left(\phi /2\right)}$ (27)

Then, the tangential force at B in obtained from

$F_{11}\cdot \sin \left(90-\phi \right)=F_{13}\sin \left(\phi /2\right)$ (28)

or

$F_{11}\cdot \cos \phi =F_{13}\sin \left(\phi /2\right)$ (29)

and, therefore,

$\frac{F_{11}}{F_{13}}=\frac{\sin \left(\phi /2\right)}{\cos \phi }=\frac{m_1{\gamma }_1^3}{4m_3{\gamma }_3^3{\sin }^2\left(\phi /2\right)}$ (30)

giving

$\frac{4{\sin }^3\left(\phi /2\right)}{\cos \phi }=\frac{m_1{\gamma }_1^3}{m_3{\gamma }_3^3}$ (31)

In view of the de Broglie condition

${\gamma }_1{m}_{1}cr={\gamma }_3{m}_{3}cr=\hslash$ (32)

we have

${\gamma }_1{m}_1={\gamma }_3{m}_3$ (33)

and since

$m_3/m_1=\frac{0.0437}{1.174\times {10}^{-3}}=37.22$ (34)

it follows that

$4\frac{{\sin }^3\left(\phi /2\right)}{\cos \phi }=37.22$ (35)

which, by trial and error, gives

$\phi ={89.95}^{\circ }$ (36)

Considering the equations of motion of the three particles and assuming $v_1\approx c$, $v_3\approx c$, it follows that

$\hslash c={\gamma }_3{m}_3{c}^{2}r=\frac{2G{m}_1{m}_3{\gamma }_1^3{\gamma }_3^3}{4\cos \left(\phi /2\right)}$ (37)

and also

${\left(\hslash c\right)}^2={\left({\gamma }_1{m}_1{c}^{2}r\right)}^2={\left[\frac{G{m}_1^2{\gamma }_1^6}{4\sin \phi }+\frac{G{m}_1{m}_3{\gamma }_1^3{\gamma }_3^3}{4\cos \left(\phi /2\right)}\right]}^2$ (38)

After multiplying by parts, accounting for the fact that

${\gamma }_1{m}_1={\gamma }_3{m}_3=\frac{\hslash }{rc}$ (39)

and defining

$x=\frac{m_1}{m_3};y=\frac{{\gamma }_1}{{\gamma }_3}$ (40)

we obtain

$\begin{array}{c}{\gamma }_1^2{\gamma }_3^3{m}_1^2{m}_3{r}^3{c}^6=\frac{{\left(\hslash c\right)}^3}{G^3{m}_3^6{\gamma }_3^{18}}={\left(\frac{m_{Pl}}{m_3}\right)}^6{\gamma }_3^{-18}\\ =\frac{2}{4^3}\left[\frac{x^5{y}^{15}}{{\sin }^2\phi \cos \left(\phi /2\right)}+\frac{2x^4{y}^{12}}{{\cos }^2\left(\phi /2\right)\sin \phi }+\frac{x^3{y}^9}{{\cos }^3\left(\phi /2\right)}\right]\end{array}$ (41)

Accounting for the condition $xy=1$, it follows from Equation (41) that

${\left[\frac{\hslash c}{G{m}_3^2{\gamma }_3^6}\right]}^3=\frac{1}{32}\left[\frac{y^{10}}{{\sin }^2\phi \cos \left(\phi /2\right)}+\frac{2y^8}{{\cos }^2\left(\phi /2\right)\sin \phi }+\frac{y^6}{{\cos }^3\left(\phi /2\right)}\right]$ (42)

and after substitution for $\phi ={89.95}^{\circ }$, we obtain

${\left[\frac{\hslash c}{G{m}_3^2{\gamma }_3^6}\right]}^3=2.37\times {10}^{14};\frac{\hslash c}{G{m}_3^2{\gamma }_3^6}=6.19\times {10}^4$ (43)

Thus, it turns out that

${\gamma }_3={\left[{\left(\frac{m_{Pl}}{m_3}\right)}^2\frac{1}{6.19\times {10}^4}\right]}^{1/6}=0.159{\left(\frac{m_{Pl}}{m_3}\right)}^{1/3}$ (44)

and, therefore,

$m_{\pi }=3{\gamma }_3{m}_3=3\times 0.159{\left(m_{Pl}{m}_3^2\right)}^{1/3}=0.159m_n$ (45)

Consequently, it was computed that

$m_{\pi }=136.6\text{MeV}/{\text{c}}^2$ (46)

in good agreement with $m_{{\pi }^{\circ }}=134.977\text{MeV}/{\text{c}}^2$ which is the experimental value [2] [3] and with the mass value of 137.82 MeV/c² computed via the use of equilateral triangular geometry and hybridization between m₁ and m₃ neutrinos leading to m₂ neutrinos [16] [17].

3. Kaon Decay Products

In this section we use the RLM to investigate the structure and mass of the Kaons.

Kaon is a meson, that comes in two types: The charged Kaon (K⁺ or K⁻), which has a mass of 493.677 MeV/c², and the neutral Kaon (K^o), which has a mass of 497.648 MeV/c².

Out of these two types, only the charged one is known to decay into a charged pion and a neutral pion. The charge of the pion depends on the charge of the Kaon that decays.

Therefore, for the charged Kaon structure, one can consider six of these hybridized neutrinos (two trios, one staggered onto the other), all rotating around a common axis, as shown in Figure 4 and Figure 5. Moreover, for the charged

Kaon (K⁺ or K⁻) there is a small charged particle (e⁺ or e⁻) at the center of this configuration, not shown in Figure 4, which dictates the Kaon charge. This e^± particle does not rotate and, thus, it contributes little by the electron or positron rest mass of (~0.511 MeV/c²) to the Kaon mass.

The decay products of the K^o and ${\bar{K}}^{\text{o}}$ (mass 497.65 MeV/c²) are $\pi \pi$ ( $K_o^o=8.95\times {10}^{-11}\text{s}$ ) and $\pi e{\nu }_e$, $\pi \mu {\nu }_{\mu }$ and $\pi \pi \pi$ ( $K_i^o=5.11\times {10}^{-8}\text{s}$ ) [2] [3]. These decay products, i.e. the muon and the pion, have recently been shown [16] [17] to contain exclusively the above intermediate mass neutrinos (i.e. with mass m₂ (≈6.95 × 10⁻³ eV/c²) in the normal hierarchy) [14] [15] [16] [17].

From the principal hadronic decay ( ${\pi }^{+}{\pi }^o$ ) of the K⁺, since the pion comprises three hybridized neutrinos [16], one may conclude that the Kaons comprise six ${\nu }_{\mu e}$ hybridized neutrinos. This is also confirmed by the leptonic Kaon decay [2] [3]. According to the RLM [17], it is possible to make an estimate of the order of magnitude of the K mass via the expression

$m_K\approx 6{\left(m_{Pl}{m}_2^2\right)}^{1/3}$ (47)

Using $m_{Pl}=1.221\times {10}^{28}\text{eV}/{\text{c}}^2$ and Equation (21) one obtains $m_K\approx 503.3\text{MeV}/{\text{c}}^2$ and this value without any detailed modeling differs already, only approximately 1% and 1.5% from the experimental values [2] [3] of 497.65 MeV/c² and 493.57 MeV/c², respectively, of the neutral Kaon K^o and of the charged Kaon K⁺.

4. RLM Model for the Kaon Structure and Mass Computation

The simplest geometric model for accommodating six rotating neutrinos placed on two equilateral triangles is a normal triangular octahedron (Figure 4 and Figure 5). We therefore hypothesize that the K structure comprises six neutrinos of mass m₂ arranged at the six vertices of a rotating normal triangular octahedron (Figure 4 and Figure 5). This structure corresponds to one of the five platonic solids and belongs to the O_h symmetry point group [21]. Therefore it comprises three C4 rotational axes (Figure 4, left) and four C3 axes (Figure 4, right).

Consequently, any of the six neutrinos can be rotating on a total of seven different axes. The energy equipartition theorem suggests that all these axial rotations contribute equally to the energy of each Kaon particle.

The total kinetic energy of the six neutrinos with rest mass m₂ each, corresponds to the rest energy, E, of the composite particle and is given by

$E=6\bar{\gamma }{m}_2{c}^2$ (48)

where $\bar{\gamma }$ denotes a mean Lorentz factor value accounting for the rotation of all six neutrinos.

Due to the Kaon particle symmetry, the Lorentz factor $\gamma$ of each rotating particle can be computed by considering the projection of each force on the seven planes of rotation (Figure 5).

Consequently, in order to find first the speeds $v_4$ and $v_3$ as well as the corresponding Lorentz factor values ${\gamma }_3$ and ${\gamma }_4$, we compute, from Figure 5(a),

$F_3=\frac{G{m}_2^2}{r^2}\left[\frac{1}{\sqrt{3}}+\frac{1}{3\sqrt{3}}+\frac{1}{3\sqrt{6}}\right]$ (49)

where F₃ is the centripetal force exerted on each of the rotating particles in the C4 mode by all the other five particles. Then, similarly as in Equation (52) below, we obtain

${\gamma }_3{m}_2\frac{c^2}{r}=\frac{G{m}_2^2{\gamma }_3^6}{r^2}\left[\frac{1}{3\sqrt{3}}+\frac{1}{3\sqrt{6}}+\frac{1}{\sqrt{3}}\right]$ (50)

We also have from Figure 5(b) that

$F_4=\frac{G{m}_2^2}{r^2}\left[\frac{2\sqrt{2}}{3}+\frac{1}{6}\right]$ (51)

where F₄ is the centripetal force exerted on each of rotating particles in the 3 mode by all the other five particles.

Accounting for the fact that $F=\gamma m{v}^2/r\approx \gamma m{c}^2/r$ we obtain for each particle the equation

${\gamma }_4{m}_2\frac{c^2}{\frac{\sqrt{6}r}{2}}=\frac{G{m}_2^2{\gamma }_4^6}{r^2}\left[\frac{2\sqrt{2}}{3}+\frac{1}{6}\right]$ (52)

Using the De Broglie angular momenta quantization equation (i.e. the De Broglie equation) (see Figure 5(a) & Figure 5(b)), we obtain

$r=\frac{\hslash }{{\gamma }_3{m}_{2}c}$ (53)

$\frac{\sqrt{6}}{2}r=\frac{\hslash }{{\gamma }_4{m}_{2}c}$ (54)

and, thus, Equations (52) and (50), yield respectively

$\frac{\hslash c}{G{m}_2^2}={\gamma }_3^6\left[\frac{1}{3\sqrt{3}}+\frac{1}{3\sqrt{6}}+\frac{1}{\sqrt{3}}\right]$ (55)

and

$\frac{\hslash c}{G{m}_2^2}={\gamma }_4^6\left[\sqrt{2}+\frac{1}{4}\right]$ (56)

Accounting for the fact that $\hslash c/G=m_{Pl}^2$, we establish the following expressions for the two Lorentz factors

${\gamma }_3={\left(\frac{m_{Pl}}{m_2}\right)}^{1/3}\frac{1}{{\left[\frac{1}{3\sqrt{3}}+\frac{1}{3\sqrt{6}}+\frac{1}{\sqrt{3}}\right]}^{1/6}}$ (57)

${\gamma }_4={\left(\frac{m_{Pl}}{m_2}\right)}^{1/3}\frac{1}{{\left[\sqrt{2}+\frac{1}{4}\right]}^{1/6}}$ (58)

On using the energy equipartition principle and recalling that there are four 3p axes and three 4p axes, the total energy per particle E is given by the expression

$E=\left[4{\gamma }_3{m}_2{c}^2+3{\gamma }_4{m}_2{c}^2\right]/7$ (59)

where the values of ${\gamma }_3$ and ${\gamma }_4$ are computed from Equations (57) and (58) as

${\gamma }_3=1.0166{\left(\frac{m_{Pl}}{m_2}\right)}^{1/3}$ (60)

${\gamma }_4=0.9186{\left(\frac{m_{Pl}}{m_2}\right)}^{1/3}$ (61)

Then, it turns out that

$\bar{\gamma }=\left[\frac{4}{7}{\gamma }_3+\frac{3}{7}{\gamma }_4\right]{\left(\frac{m_{Pl}}{m_2}\right)}^{1/3}=0.9746{\left(\frac{m_{Pl}}{m_2}\right)}^{1/3}$ (62)

and, thus, accounting for the six particles in the Kaon, it follows that

$m_K=6\bar{\gamma }{m}_2=0.9746\times 503\times {10}^6\text{eV}/{\text{c}}^2=490.5\text{MeV}/{\text{c}}^2$ (63)

which differs less than 0.7% from the experimental value of 493.677 MeV/c² [2] [3].

Consequently, the final formula for the Kaon mass is

$\begin{array}{c}{m}_K=6\left\{\frac{4}{7}\frac{1}{{\left[\frac{1}{3\sqrt{3}}+\frac{1}{3\sqrt{6}}+\frac{1}{\sqrt{3}}\right]}^{1/6}}+\frac{3}{7}\frac{1}{{\left[\sqrt{2}+\frac{1}{4}\right]}^{1/6}}\right\}{\left(m_{Pl}{m}_2^2\right)}^{1/3}\\ =490.5\text{MeV}/{\text{c}}^2\end{array}$ (64)

If we add the mass of the central e⁺, then the computed m_K value attains the value $m_K=491.0\text{MeV}/{\text{c}}^2$ and the deviations from the experimental K^± value is 0.55%, while from the experimental K^o value is 1.4%.

5. Conclusions

The present study shows that the Rotating Lepton Model (RLM) which combines the de Broglie wavelength equation, which has been the basis of quantum mechanics, with special relativity and with Newton’s Universal gravitational Law, provides, without any adjustable parameters, a very good fit to the masses of Pions and of Kaons. Kaons are found to be three-dimensional rotating structures comprising hybridized rotating relativistic neutrinos with a mass corresponding to the m₂ neutrino mass of the normal hierarchy. So far the RLM has been used to model only one 3D particle structure, i.e. that of the Higgs boson [19].

The neutrinos of the Kaon structure result from the hybridization of the m₁ and m₃ flavor type neutrinos, and are the same ones used already to compute the masses of muons [16] and pions [16]. It is worth noting that, similarly to the cases of the proton and the neutron masses, (938.272 MeV/c² and 939.565 MeV/c² respectively), which comprise only mass m₃ neutrinos and where the neutral composite particle (n) is heavier, here also the neutral composite particle (K^o) has higher mass than the charged one (K^±). This has been attributed to the fact that electrostatic forces (between quarks [2] [3], or resulting from charge-induced dipole interactions, similar to van der Waals forces in chemistry, [21], enhance the total attraction and thus lower the required $\gamma$ value for the gravitational confinement of the rotating neutrinos [14].

In conclusion, it should be pointed out that various Yukawa-type potentials [4] [23] have been proposed to model the rapid decay of strong nuclear force at a rate much faster than the inverse square low (~1/r²) of Coulombic interactions for separation distances at the femtometer range. This is done by solving a “homogeneous” Helmholtz equation involving an additional phenomenological coefficient. An alternative nonlocal gradient intreaction force has been introduced more recently [24] leading to an “in homogeneous” Helmholtz equation, the solution of which also involves an adjustable phenomenological coefficient, which conveniently serves to effectively interpret non-Coulombic internuclear interactions. The RLM free-parameter approach can be directly used to properly determine the values of the aformentioned phenomenological coefficients.

The present study also confirms the conclusion [17] that neutrinos, electrons and positrons are apparently the only undividable elementary particles, as evidenced by examining the decay products of all the Tables of Elementary particles [2] [3]. Consequently these elementary particles are the equivalent of atoms in chemistry.

Acknowledgements

This research was co-financed by the Greek State and the European Union (European Social Fund—ESF) through the Operational Programme Human Resources Development, Education and Lifelong Learning in the context of the project Reinforcement of Postdoctoral Researchers—2^nd Cycle (MIS-5033021), implemented by the State Scholarships Foundation (IKY).

Conflicts of Interest

The authors declare no conflicts of interest regarding the publication of this paper.

References

[1]	Vayenas, C.G., Tsousis, D., Grigoriou, D., Parisis, K. and Aifantis, E. (2022) Hadronization via Gravitational Confinement of Fast Neutrinos: Mechanics at FM Distances. Zeitschrift für Angewandte Mathematik und Mechanik, 102, e202100158. https://doi.org/10.1002/zamm.202100158
[2]	Griffiths, D. (2008) Introduction to Elementary Particles. 2nd Edition, Wiley-VCH Verlag GmbH & Co. KgaA, Weinheim.
[3]	Tully, C.G. (2011) Elementary Particle Physics in a Nutshell. Princeton University Press, Princeton.
[4]	Kajita, T. (2006) Nobel Lecture: Discovery of Atmospheric Neutrino Oscillations. Reports on Progress in Physics, 69, 1607-1635. https://doi.org/10.1088/0034-4885/69/6/R01
[5]	McDonald, A.B. (2016) Nobel Lecture: The Sudbury Neutrino Observatory: Observation of Flavor Change for Solar Neutrinos. Reviews of Modern Physics, 88, Article ID: 030502. https://doi.org/10.1103/RevModPhys.88.030502
[6]	Mohapatra, R.N., et al. (2007) Theory of Neutrinos: A White Paper. Reports on Progress in Physics, 70, 1757-1867. https://doi.org/10.1088/0034-4885/70/11/R02
[7]	Formaggio, J.A. and Zeller, G.P. (2012) From eV to EeV: Neutrino Cross Sections across Energy Scales. Reviews of Modern Physics, 84, 1307-1341. https://doi.org/10.1103/RevModPhys.84.1307
[8]	Formaggio, J.A., de Gouva, A.-L.C. and Hamish Robertson, R.G. (2021) Direct Measurements of Neutrino Mass. Physics Reports, 914, 1-54. https://doi.org/10.1016/j.physrep.2021.02.002
[9]	Bohr, N. (1913) On the Constitution of Atoms and Molecules. Part I. Philosophical Magazine, 26, 1-25. https://doi.org/10.1080/14786441308634955
[10]	Einstein, A. (1905) Zür Elektrodynamik bewegter Körper. Annalen der Physik, 17, 891-921. https://doi.org/10.1002/andp.19053221004
[11]	French, A.P. (1968) Special Relativity. W.W. Norton and Co., New York.
[12]	Wald, R.M. (1984) General Relativity. The University of Chicago Press, Chicago. https://doi.org/10.7208/chicago/9780226870373.001.0001
[13]	De Broglie, L. (1923) Waves and Quanta. Nature, 112, 540. https://doi.org/10.1038/112540a0
[14]	Vayenas, C.G. and Souentie, S. (2012) Gravity, Special Relativity and the Strong Force: A Bohr-Einstein-de-Broglie Model for the Formation of Hadrons. Springer, New York. https://doi.org/10.1007/978-1-4614-3936-3
[15]	Vayenas, C.G., Souentie, S. and Fokas, A. (2014) A Bohr-Type Model with Gravity as the Attractive Force. Physica A, 405, 360-379. https://doi.org/10.1016/j.physa.2014.03.045
[16]	Vayenas, C.G. and Grigoriou, D.P. (2019) Hadronization via Gravitational Confinement. In: Studenikin, A., Ed., Particle Physics at the Year of 25th Anniversary of the Lomonosov Conferences, World Scientific, Singapore, 517-524. https://doi.org/10.1142/9789811202339_0092
[17]	Vayenas, C.G., Tsousis, D. and Grigoriou, D. (2020) Computation of the Masses, Energies and Internal Pressures of Hadrons, Mesons and Bosons via the Rotating Lepton Model. Physica A, 545, Article ID: 123679. https://doi.org/10.1016/j.physa.2019.123679
[18]	Vayenas, C.G., Fokas, A.S. and Grigoriou, D. (2016) On the Structure, Masses and Thermodynamics of the W Bosons. Physica A, 450, 37-48. https://doi.org/10.1016/j.physa.2015.12.120
[19]	Fokas, A.S., Vayenas, C.G. and Grigoriou, D. (2018) On the Mass and Thermodynamics of the Higgs Boson. Physica A, 492, 737-746. https://doi.org/10.1016/j.physa.2017.11.003
[20]	Murtzen, E. (2021) The Rotating Lepton Model: Combining Fundamental Theories. Research Features, 137, Article ID: 102105. https://researchfeatures.com/publications/research-features-magazine-137
[21]	Pauling, L. (1960) The Nature of the Chemical Bond. 3rd Edition, Oxford University Press, Oxford, 111-120.
[22]	Aartsen, M.G., et al. (2018) Measurement of Atmospheric Neutrino Oscillations at 6-56 GeV with IceCube DeepCore. Physical Review Letters, 120, Article ID: 071801.
[23]	Yukawa, H. (1955) On the Interaction of Elementary Particles. I and II. Progress of Theoretical Physics Supplements, 1, 110 & 14-23.
[24]	Aifantis, E.C. (2020) A Concise Review of Gradient Models in Mechanics and Physics. Frontiers in Physics, 7, Article No. 239. https://doi.org/10.3389/fphy.2019.00239