JP2018007322A - Δ-(1232), σ-, ξ-, and ω- - Google Patents

Abstract

PROBLEM TO BE SOLVED: To understand an orbit of a quark.SOLUTION: In Application Number 2016-094933 "quark 2" applied on 10 May 2016, calculation is performed by regarding the quark energy on the ground surface as 1/(3×10). Consequently, the orbit is multiplied by 3×10. However, among protons on the ground surface, the mass energy of a 3.1-MeV u quark is 3.1 MeV, for example. Therefore, a quark orbit is considered again by correcting the quark energy on the ground surface that has been investigated. Since "unification of the particle mass and the electromagnetic mass" is possible, the orbital energy of one electromagnetic entity is 1.233×10J m; since a quark is formed by 6.249×10electromagnetic entities coupled to each other, the orbital energy of the quark is 1.233×10J m×6.249×10=7.705×10J m. Since other particles in an electron or proton are an entity formed by 7.028×10electromagnetic entities coupled together, the particle orbital energy is 1.233×10J m×7.028×10=8.665×10J m.SELECTED DRAWING: Figure 1

Description

The present invention, Δ ^- (1232), Σ ^{chromatography,} Ξ ^-, Ω ^- relates.

In "Neutron, Δ ⁰ , Σ ⁰ , Ξ ⁰ " of Japanese Patent Application No. 2016-123108 filed on June 22, 2016, we thought as follows.
For example, the composition of neutrons is the u-quark, d-quark, d-quark and the center thing. What is the structure?
Neutrons are composed of the central object, u-quark, d-quark and d-quark. How is it rotating?
About neutron love.
What is the orbit of a quark rotating around a neutron lab?
Quark energy and orbital relation, orbit = 2.312 × 10 ⁻²⁴ Jm ÷ quark energy.
Δ ^- (1232), Σ ^over, Ξ ^-, Ω ^- think in the same way also.

Patent application 2016-085977 Japanese Patent Application 2016-094933 Japanese Patent Application 2016-114926 Japanese Patent Application 2016-123108

1． Δ ^- the configuration of the (1232) is, Δ ^- (1232) and Love and the d quark of, and the d quark, is the d quark. What is the structure?
2． Δ ⁻ (1232) is composed of a love of Δ ⁻ (1232), a d-quark of 4.1 MeV, a d-quark of 4.9 MeV, and a d-quark of 5.7 MeV. How is it rotating? 1
3． Orbital and energy calculations
Four. How should the quark trajectory be calculated?
Five. Δ ⁻ (1232) is composed of a love of Δ ⁻ (1232), a d-quark of 4.1 MeV, a d-quark of 4.9 MeV, and a d-quark of 5.7 MeV. How is it rotating? 2
6． Σ ^- the configuration of, Δ ^- (1232) and Love and the d quark of, and the d quark, is s quark. What is the structure?
7． Σ ^- it is Σ ^- constituted by the love and 4.1MeV of the d quark and 5.7MeV of the d quark and 130MeV of s quark. How is it rotating?
8． Ξ ^- the configuration of, Ξ ^- Love and the d quark of, and s quarks, is s quark. What is the structure?
9． Ξ ⁻ is composed of Ξ ⁻ love, 5.7 MeV d quark, 80 MeV s quark and 130 MeV s quark. How is it rotating?
Ten. Ω ^- the configuration of, Ω ^- and Love and s quarks of, and s quarks, is s quark. What is the structure?
11． Ω ⁻ is composed of Ω ⁻ love, 80 MeV s quark, 105 MeV s quark and 130 MeV s quark. How is it rotating?
12． What kind of particles are love?
13. ^{Δ - (1232), Σ -} , Ξ -, Ω - the "unity of mass and electromagnetic mass particles" How in either.
14. What is the mass energy of a quark rotating in the lab?
15． What is the path of a quark rotating in the love?

1． Since the d quark is 4.1MeV to 5.7MeV, it is assumed to be 4.1MeV d quark, 4.9MeV d quark and 5.7MeV d quark.
Δ ⁻ Mass energy of (1232) lab = Δ ⁻ Mass energy of (1232) − (4.1 MeV d quark + 4.9 MeV d quark + 5.7 MeV d quark)
Δ ⁻ Mass energy of (1232) lab = 1232MeV- (4.1MeV + 4.9MeV + 5.7MeV) = 1232MeV-14.7MeV = 1217.3MeV = 1217.3 × 1.602 × 10 ^-19 J × 10 ⁶ = 1.950 × 10 ^-10 J
What is the revolution trajectory of the Δ ⁻ (1232) love? How much energy can an electric photon be produced in one revolution? Δ ^- (1232) or love is what one of the electromagnetic has become one bundle. Spinning orbit of magnetic photons. The energy of one magnetic photon. How much is A where Δ ⁻ (1232) love exists? Ask them.
2． Quark trajectory = 2.312 × 10 ⁻²⁴ Jm ÷ Calculate the quark trajectory using the formula of quark energy.
3． The energy of one electric photon is 1.233 × 10 ^-41 Jm ÷ (2.532 × 10 ^-12 m) = 4.870 × 10 ^-30 J.
The quark is a collection of 6.249 × 10 ⁸ electromagnetics in one lump, so this energy is 6.249 × 10 ⁸ × 4.870 × 10 ^-30 J = 3.043 × 10 ^-21 J.
5.7MeV = 5.7 × 1.602 × 10 ^-19 J × 10 ⁶ = 9.131 × 10 ^-13 J
How many 5.7 MeV is the energy of an electric photon?
9.131 × 10 ^-13 J ÷ (4.870 × 10 ^-30 J) = 1.875 × 10 ¹⁷
5.7MeV is the energy of 1.875 × 10 ¹⁷ electrical photons.
This is a multiple of 6.249 × 10 ⁸ pieces.
1.875 × 10 ¹⁷ pieces ÷ (6.249 × 10 ⁸ pieces) = 3.000 × 10 ⁸ times This is 6.249 × 10 ⁸ pieces 3.000 × 10 ⁸ times.
Four. Since the quark is a mass of 6.249 × 10 ⁸ electromagnetics gathered, the orbital energy of the quark is 1 orbital electromagnetic energy × 6.249 × 10 ⁸ = 1.233 × 10 ⁻⁴¹ Jm × 6.249 × 10 ⁸ = 7.705 × 10 ⁻³³ Jm.
Five. Quark orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark's orbit is calculated according to the equation of mass energy of quark.
6． The quarks are 4.1MeV d quarks, 5.7MeV d quarks and 130MeV s quarks.
Sigma ^- Rab mass energy + 4.1MeV the d quark + 5.7MeV the d quark + 130MeV of s quark sigma ^{- -} mass energy - ^- Mass Energy = sigma Rab mass energy = sigma of (4.1MeV the d quark +5 .7MeV d quark + 130MeV s quark) = 1119.449MeV-(4.1MeV + 5.7MeV + 130MeV) = 1119.449MeV-139.8MeV = 1057.649MeV = 1057.649 x 1.602 x 10 ^-19 J x 10 ⁶ = 1.694 x 10 ^-10 J
Σ ^- the orbit of Love somewhat. How much energy can an electric photon be produced in one revolution? Σ ^- Is love what one of electromagnetism is in one bundle. Spinning orbit of magnetic photons. The energy of one magnetic photon. Σ ^- the place of A Love to presence of some. Ask them.
7． Quark orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark's orbit is calculated according to the equation of mass energy of quark.
8． The quarks are 5.7 MeV d quarks, 80 MeV s quarks and 130 MeV s quarks.
.XI ^- Mass Energy = .XI ^- Rab mass energy + 5.7MeV the d quark + 80 meV of s quark + 130MeV of s quark .XI ^- mass energy - ^- Mass Energy = .XI Rab (5.7MeV the d quark + 80 meV for s Quark + 130MeV s Quark) = 1314.9MeV- (5.7MeV + 80MeV + 130MeV) = 1314.9MeV-215.7MeV = 1099.2MeV = 1099.2 x 1.602 x 10 ^-19 J x 10 ⁶ = 1.761 x 10 ^-10 J
Ξ ^- the orbit of Love somewhat. How much energy can an electric photon be produced in one revolution? Ξ ^- Is love what one of electromagnetism is in one bundle. Spinning orbit of magnetic photons. The energy of one magnetic photon. Ξ ^- the place of A Love to presence of some. Ask them.
9． Quark orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark's orbit is calculated according to the equation of mass energy of quark.
Ten. The quarks are 80MeV s quarks, 105MeV s quarks and 130MeV s quarks.
Omega ^- of Rab mass energy + 80 meV of s quark + 105MeV of s quark + 130MeV s quark Omega ^{- -} mass energy - ^- Mass Energy = Omega Rab (the s quark + 105MeV of 80 meV in the s quark + 130MeV mass energy = Omega of s quark) = 1672.45MeV- (80MeV + 105MeV + 130MeV) = 1672.45MeV-315MeV = 1357.45MeV = 1357.45 × 1.602 × 10 ^-19 J × 10 ⁶ = 2.175 × 10 ^-10 J
Ω ^- the orbit of Love somewhat. How much energy can an electric photon be produced in one revolution? Ω ^- Is love what one of electromagnetism is in one bundle. Spinning orbit of magnetic photons. The energy of one magnetic photon. Ω ^- the place of A Love to presence of some. Ask them.
11． Quark orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark's orbit is calculated according to the equation of mass energy of quark.
12． Δ ^- (1232) Love and Σ ^- of Love and Ξ ^- of Love and Ω ^- Love is summarized whether the how to made of.
13. "Unification of particle mass and electromagnetic mass"
Particle = electromagnetism of one bundle of electromagnetic waves = 7.028 × 10 ¹⁷ electromagnetism = particles of one electromagnetic bundle = mass of Love particles = E ÷ c ^{2 The} mass of the particles (particles of one electromagnetic bundle) is obtained.
The mass of the particles (particles of one electromagnetic bundle) is obtained by the following equation: mass of particles = 9.628 × 10 ⁻⁴¹ Jm ÷ orbital.
The mass of the particles (one electromagnetic bundle) is obtained by the following equation: mass of particles = 1.111 × 10 ⁻¹⁷ × particle energy.
The mass of one electromagnetic particle is obtained by the following equation: mass of one electromagnetic particle = mass of particle (mass of electromagnetic particle) ÷ electromagnetic number of one bundle.
The mass of one electromagnetic particle is obtained by the following equation: mass of one electromagnetic particle = 1.370 × 10 ⁻⁵⁸ Jm ÷ orbital.
Find the value of the energy of one electromagnetic particle ÷ the mass of one electromagnetic particle.
14. Delta ^- (1232) Love and Σ of ^- Rab and .XI ^- Love and Omega ^- rotating the through Love, to calculate the mass energy × 100, the value of the mass energy ÷ Rab Quark
15． The table shows the orbit of the quarks rotating in the lab.

1． A table of objects constituting Δ ⁻ (1232) is shown below.
2． The table below shows the rotation and revolution trajectories of the Δ ⁻ (1232) lab, the 4.1 MeV d-quark trajectory, the 4.9 MeV d-quark trajectory and the 5.7 MeV d-quark trajectory rotating around it.
3． Thus since the cause was a surface energy 5.7MeV of (3 × 10 ⁸⁾ content of 1 energy ^{= 9.131 × 10 -13 J ÷ (} 3 × 10 8) = 3.044 × 10 -21 J, and Because.
The energy of the quark in Δ ⁻ (1232) is 5.7 MeV, so this is the electromagnetic orbit.
This correction will be made in the next patent application.
4). The orbital energy is shown in the table.
Five. The table shows the rotation and revolution trajectories of the Δ ⁻ (1232) lab, the 4.1 MeV d-quark trajectory, the 4.9 MeV d-quark trajectory, and the 5.7 MeV d-quark trajectory rotating inside it.
6． It shows a table of objects that make up the ^- sigma.
7． Sigma ^- shown in the table rotation trajectory and orbit the orbit of s quark orbital and 130 MeV d-quark orbital and 5.7MeV of d Quark 4.1MeV to rotate therein Rab.
8． .XI ^- shows a table of objects that make up the.
9． .XI ^- of the Love rotation trajectory and orbit the track and the track of the s quark of 130 MeV of s quark orbital and 80MeV the d quark of 5.7MeV to rotate therein are shown in Table.
Ten. It shows a table of objects that make up the ^- Omega.
11． Omega ^- are shown in the tables rotation trajectory and orbit the orbit of s quark orbital and 130 MeV of s quark orbital and 105MeV of s Quark 80MeV to rotate therein Rab.
12． The table shows the love of Δ ⁻ (1232), the love of Σ ⁻ , the love of Ξ ^{− and} the love of Ω ⁻ .
13. The mass energy of the lab, the orbit of the lab, the electromagnetic number of the lab, the energy of one photon generated by the lab in one revolution and the mass of the particle = E ÷ c ² and the mass of the particle = 9.628 × 10 ^-41 Jm ÷ Orbit, particle mass = 1.111 × 10 ⁻¹⁷ × particle energy, one electromagnetic particle mass = particle mass ÷ electromagnetic number, and one electromagnetic particle mass = 1.370 × 10 ⁻⁵⁸ Jm ÷ orbital Table 1 shows the energy of one electromagnetic particle divided by the mass of one electromagnetic particle.
14. Delta ^- Love and Σ of (1232) ^- Love and Ξ of ^- Love and Ω of ^- mass energy of quark rotating through Rab is shown in the table as a percentage of the mass energy of love.
15． Delta ^- Love and Σ of (1232) ^- Love and Ξ of ^- Love and Ω of ^- the trajectory of quark which rotates in Rab shown in Table. This is illustrated.

FIG. 1 illustrates the orbit of a quark rotating in a Δ ⁻ (1232) lab, a Σ ⁻ lab, a Ξ ⁻ lab and a Ω ⁻ lab. Δ ^- Love orbit of the (1232) is 4.444 × 10 ^-14 m. Three quarks: 5.7MeV d-quark, 4.9 MeV d-quark, 4.1MeV d-quark. And The 5.7 MeV d-quark rotates counterclockwise on an orbit of 8.438 × 10 ⁻²¹ m. The 4.9 MeV d quark rotates counterclockwise on a 9.815 × 10 ⁻²¹ m track. The 4.1MeV d-quark rotates counterclockwise on a 1.173 × 10 ⁻²⁰ m track. Σ ^- the orbit of the Love is 5.115 × 10 ^-14 m. The three quarks will be 130 MeV s quarks, 5.7 MeV d quarks, and 4.1 MeV d quarks. The 130MeV s quark rotates counterclockwise on a 3.699 × 10 ^-22 m track. The 5.7 MeV d-quark rotates counterclockwise on an orbit of 8.438 × 10 ⁻²¹ m. The 4.1 MeV d-quark rotates counterclockwise on a 1.173 × 10 ⁻²⁰ m track. Ξ ^- the orbit of the Love is 4.920 × 10 ^-14 m. The three quarks will be 130MeV s quarks, 80MeV s quarks and 5.7MeV d quarks. The 130MeV s quark rotates counterclockwise on a 3.699 × 10 ⁻²² m orbit. An 80MeV s quark rotates left on a 6.010 × 10 ⁻²² m orbit. The 5.7 MeV d-quark rotates counterclockwise on an orbit of 8.438 × 10 ⁻²¹ m. Ω ^- the orbit of the Love is 3.984 × 10 ^-14 m. The three quarks will be 130MeV s quarks, 105MeV s quarks, and 80MeV s quarks. The 130MeV s quark rotates counterclockwise on a 3.699 × 10 ⁻²² m orbit. The 105MeV s quark rotates counterclockwise on a 4.581 × 10 ⁻²² m track. An 80MeV s quark rotates left on a 6.010 × 10 ⁻²² m orbit.

1. Δ ^- the configuration of the (1232) is, Δ ^- (1232) and Love and the d quark of, and the d quark, is the d quark. What is the structure?
Since the mass energy of Δ ⁻ (1232) is 1231 MeV to 1233 MeV, it is an intermediate value, 1232 MeV = 1232 × 1.602 × 10 ^-19 J × 10 ⁶ = 1.974 × 10 ^-10 J And
Since the d quark is 4.1MeV to 5.7MeV, it is assumed to be 4.1MeV d quark, 4.9MeV d quark and 5.7MeV d quark.
Δ ⁻ Mass energy of (1232) = Δ ⁻ Mass energy of lab of (1232) + 4.1MeV d quark + 4.9MeV d quark + 5.7MeV d quark Δ ⁻ Mass energy of lab of (1232) = Δ ⁻ Mass energy of (1232)-(4.1MeV d quark + 4.9MeV d quark + 5.7MeV d quark)
Δ ⁻ Mass energy of (1232) lab = 1232MeV- (4.1MeV + 4.9MeV + 5.7MeV) = 1232MeV-14.7MeV = 1217.3MeV = 1217.3 × 1.602 × 10 ^-19 J × 10 ⁶ = 1.950 × 10 ^-10 J
The revolution trajectory of the lab of Δ ⁻ (1232) is 8.665 × 10 ⁻²⁴ Jm ÷ (1.950 × 10 ⁻¹⁰ J) = 4.444 × 10 ⁻¹⁴ m.
The energy of one electric photon generated per revolution is 1.233 × 10 ⁻⁴¹ Jm ÷ (4.444 × 10 ⁻¹⁴ m) = 2.775 × 10 ⁻²⁸ J.
Delta ^- Electromagnetic number Rab (1232) is, delta ^- (1232) Energy = 1.950 × 10 ^-10 J ÷ Love single photon mass energy ÷ electricity of ^{(2.775 × 10 -28 J) =} 7.027 × 10 ¹⁷ (pieces)
Magnetic photon rotation orbit = Electric photon rotation orbit x 3.14 ÷ 1 revolution rotation number = 4.444 x 10 ^-14 m x 3.14 ÷ (4.34 x 10 ⁴ times) = 3.215 x 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.775 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 6.394 x 10 ^-33 J
Δ ⁻ (1232) where the lab is formed A = revolution trajectory of the earth's electron lab ÷ Δ ⁻ (1232) lab's orbit = 1.058 × 10 ^-10 m ÷ (4.444 × 10 ^-14 m) = 2.381 × 10 ³

This is shown in the table.
Table 1 composing Δ ⁻ (1232)

2. Δ ⁻ (1232) is composed of a love of Δ ⁻ (1232), a d-quark of 4.1 MeV, a d-quark of 4.9 MeV, and a d-quark of 5.7 MeV. How is it rotating? 1
The revolution trajectory of Δ ⁻ (1232) lab is 4.444 × 10 ^-14 m.
Around this, d-quarks are rotating.
What is the trajectory of the 4.1MeV d-quark?
Orbit = 2.312 × 10 ⁻²⁴ Jm ÷ Quark energy = 2.312 × 10 ⁻²⁴ Jm ÷ (4.1 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 2.312 × 10 ⁻²⁴ Jm ÷ (6.568 × 10 ^-13 J) = 3.520 × 10 ^-12 m
The orbit of 4.1MeV d-quark is 3.520 × 10 ^-12 m.
4.9 What is the orbit of the MeV d-quark?
Orbit = 2.312 × 10 ⁻²⁴ Jm ÷ Quark energy = 2.312 × 10 ⁻²⁴ Jm ÷ (4.9 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 2.312 × 10 ⁻²⁴ Jm ÷ (7.850 × 10 ^-13 J) = 2.945 × 10 ^-12 m
The orbit of a 4.9MeV d-quark is 2.945 × 10 ^-12 m.
What is the orbit of a 5.7 MeV d-quark?
Orbit = 2.312 × 10 ⁻²⁴ Jm ÷ Quark energy = 2.312 × 10 ⁻²⁴ Jm ÷ (5.7 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 2.312 × 10 ⁻²⁴ Jm ÷ (9.131 × 10 ^-13 J) = 2.532 × 10 ^-12 m

It is summarized in the table.
Rotation and revolving orbit of Δ ⁻ (1232) lab, 4.1MeV d-quark orbit, 4.9MeV d-quark orbit, and 5.7MeV d-quark orbit around the circumference Table 2

Δ ⁻ (1232) revolves around a 4.444 × 10 ⁻¹⁴ m orbit while the love of Δ ⁻ (1232) rotates around the orbit of 3.215 × 10 ⁻¹⁸ m.
The 5.7MeV d-quark rotates counterclockwise on the outer 2.532 × 10 ^-12 m orbit. Furthermore, the 4.9MeV d-quark is rotating counterclockwise on the outer 2.945 × 10 ^-12 m orbit. The 4.1MeV d-quark rotates counterclockwise on the outermost orbit of 3.520 × 10 ^-12 m.

3. Calculation of orbit and energy delta ^- (1232) Rab is rotation the trajectory of 3.215 × 10 ^-18 m, the magnetic photon one energy making is 6.394 × 10 ^-33 J. Since one revolution is 4.34 × 10 ⁴ rotations, the energy of a magnetic photon created by one revolution is 6.394 × 10 ⁻³³ J × 4.34 × 10 ⁴ rotations = 2.775 × 10 ⁻²⁸ J.
At the same time, the Δ ⁻ (1232) lab revolves around an orbit of 4.444 × 10 ^-14 m, creating one photon of 2.775 × 10 ⁻²⁸ J in one revolution.
The energy of magnetic photons created by the lab of Δ ⁻ (1232) is equal to the energy of electric photons.
Photons and magnetic photons of this electricity is in orbit 2.532 × 10 ^-12 m, are made to d quark of 5.7MeV become a 6.249 × 10 ⁸ cells bound 1 mass.
These photons are coupled with magnetic photons, and the total number of magnetic photons is the number of electrical photons x 4.34 x 10 ⁴ rotations = 6.249 x 10 ⁸ x 4.34 x 10 ⁴ rotations = 2.712 x 10 ¹³ pieces.
The energy of one electric photon is 1.233 × 10 ^-41 Jm ÷ (2.532 × 10 ^-12 m) = 4.870 × 10 ^-30 J.
The quark is a collection of 6.249 × 10 ⁸ electromagnetics in one lump, so this energy is 6.249 × 10 ⁸ × 4.870 × 10 ^-30 J = 3.043 × 10 ^-21 J.
5.7MeV = 5.7 × 1.602 × 10 ^-19 J × 10 ⁶ = 9.131 × 10 ^-13 J
How many 5.7 MeV is the energy of an electric photon?
9.131 × 10 ^-13 J ÷ (4.870 × 10 ^-30 J) = 1.875 × 10 ¹⁷
5.7MeV is the energy of 1.875 × 10 ¹⁷ electrical photons.
This is a multiple of 6.249 × 10 ⁸ pieces.
1.875 × 10 ¹⁷ pieces ÷ (6.249 × 10 ⁸ pieces) = 3.000 × 10 ⁸ times This is 6.249 × 10 ⁸ pieces 3.000 × 10 ⁸ times.
That is, when the orbit of an electric photon is 2.532 × 10 ^-12 m, the energy of one electric photon is 4.870 × 10 ^-30 J, and the energy gathered by 6.249 × 10 ⁸ is 3.043 × 10 ^-21 J .
This energy is one of 3.000 × 10 ⁸ minutes of 5.7MeV.
Thus since the cause was a surface energy 5.7MeV of (3 × 10 ⁸⁾ content of 1 energy ^{= 9.131 × 10 -13 J ÷ (} 3 × 10 8) = 3.044 × 10 -21 J, and Because.
Then, the energy of one electromagnetic is 3.044 × 10 ^-21 J ÷ (6.249 × 10 ⁸ pieces) = 4.871 × 10 ⁻³⁰ J, and this orbit is 1.233 × 10 ⁻⁴¹ Jm ÷ (4.871 × 10 ⁻³⁰ J ) = 2.531 × 10 ⁻¹² m.
The energy of the quark in Δ ⁻ (1232) is 5.7 MeV, so this is the electromagnetic orbit.
That is, the energy of one electromagnetic is 5.7MeV ÷ (6.249 × 10 ⁸ pieces) = 9.131 × 10 ⁻¹³ J ÷ (6.249 × 10 ⁸ pieces) = 1.461 × 10 ⁻²¹ J. The electromagnetic orbit is 1.233 × 10 ⁻⁴¹ Jm ÷ (1.461 × 10 ⁻²¹ J) = 8.439 × 10 ⁻²¹ m.
This is data in the high energy accelerator of Japanese Patent Application No. 09-09333 “Quark 2” submitted on May 10, 2016.
So we have to correct the issues, the central ones and the quarks that have been submitted so far.
This correction will be made in the next patent application.

This is shown in the table.
Data on the surface and surface of the high energy accelerator of Japanese Patent Application No. 2016-094933 “Quark 2” submitted on May 10, 2016
For 5.7 MeV d-quark Table 3

The energy of the quark on the surface is 9.131 × 10 ⁻¹³ J ÷ (3 × 10 ⁸ ) = 3.044 × 10 ⁻²¹ J.
So the orbit is 2.531 × 10 ⁻¹² m.
However, the energy of d-quark of 5.7MeV on the surface is 5.7MeV = 9.131 × 10 ⁻¹³ J.
The orbit is 8.439 × 10 ⁻²¹ m.

4). How should the quark trajectory be calculated?
The orbit of the electron lab or proton lab was obtained by the formula: orbital = 8.665 x 10 ^-24 Jm ÷ energy.
In the case of one electromagnet, it was obtained by the equation: orbital = 1.233 × 10 ⁻⁴¹ Jm ÷ energy of one electromagnet.
And, in “Claim 15” of Japanese Patent Application No. 2016-114926 “Yoko, Δ ⁺ (1232), Σ ⁺ , Λ ⁺ _c ” filed on June 9, 2016, it was written as follows.
(15. Particle orbital energy is 8.665 × 10 ⁻²⁴ Jm. Electromagnetic orbital energy is 1.233 × 10 ⁻⁴¹ Jm. What does this mean?
How many times the orbital energy of particles is the electromagnetic orbital energy?
Particle orbital energy ÷ Electromagnetic orbital energy = 8.665 × 10 ⁻²⁴ Jm ÷ (1.233 × 10 ⁻⁴¹ Jm) = 7.028 × 10 ¹⁷
The orbital energy of particles is 7.028 × 10 ¹⁷ times the electromagnetic orbital energy.
This means that 7.028 × 10 ¹⁷ electromagnets gather and form particles.
This is orbital energy = orbital mass energy.
From "Unification of particle mass and electromagnetic mass"
Because energy = mass energy.
Orbital energy of particles = electromagnetic orbital energy x 7.028 x 10 ¹⁷
Orbital mass energy of particles = electromagnetic orbital mass energy x 7.028 x 10 ¹⁷
(This indicates that 7.028 × 10 ¹⁷ electromagnetism gathers into particles)
From the above, the quark is a mass of 6.249 × 10 ⁸ electromagnetics gathered, so the orbital energy of the quark is 1 electromagnetic orbital energy × 6.249 × 10 ⁸ = 1.233 × 10 ⁻⁴¹ Jm It is considered that × 6.249 × 10 ⁸ = 7.705 × 10 ⁻³³ Jm.
Therefore, the orbit of a 5.7MeV quark is orbit = 7.705 × 10 ⁻³³ Jm ÷ 5.7MeV = 7.705 × 10 ⁻³³ Jm ÷ (9.131 × 10 ⁻¹³ J) = 8.438 × 10 ⁻²¹ m.
This data is the same as the data filed on May 10, 2016 in the high energy accelerator of Japanese Patent Application No. 2016-094933 “Quark 2”.
Therefore, the orbital energy of quarks is 7.705 × 10 ⁻³³ Jm.

This is noted in the table.
Orbital energy table 4

5. Δ ⁻ (1232) is composed of a love of Δ ⁻ (1232), a d-quark of 4.1 MeV, a d-quark of 4.9 MeV, and a d-quark of 5.7 MeV. How is it rotating? 2
The revolution trajectory of Δ ⁻ (1232) lab is 4.444 × 10 ^-14 m.
The quark is rotating in this.
What is the orbit of a 5.7MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (5.7 × 1.602 × 10 ⁻¹⁹ J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (9.131 × 10 ⁻¹³ J) = 8.438 × 10 ⁻²¹ m
What is the orbit of a 4.9MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (4.9 × 1.602 × 10 ⁻¹⁹ J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (7.850 × 10 ⁻¹³ J) = 9.815 × 10 ⁻²¹ m
What is the trajectory of the 4.1MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (4.1 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (6.568 × 10 ⁻¹³ J) = 1.173 × 10 ⁻²⁰ m

It is summarized in the table.
Rotation and revolving orbits of the lab of Δ ⁻ (1232), 4.1MeV d-quark orbit, 4.9MeV d-quark orbit and 5.7MeV d-quark orbit rotating in it

The Δ ⁻ (1232) lab rotates on a 3.215 × 10 ^-18 m orbit, creating a magnetic photon, and revolving on a 4.444 × 10 ^-14 m orbit, creating an electric photon.
The 5.7MeV d quark rotates left on the orbit of 8.438 × 10 ⁻²¹ m, the outer 4.9 MeV d quark rotates left on the orbit of 9.815 × 10 ⁻²¹ m, and the outer 4.1 MeV. The d-quark is rotating left about 1.173 × 10 ⁻²⁰ m.

6). Σ ^- the configuration of, Δ ^- (1232) and Love and the d quark of, and the d quark, is s quark. What is the structure?
Sigma ^- mass energy, 1197.449MeV = 1197.449 × 1.602 × 10 -19 J × 10 6 = 1.918 × 10 -10 J is.
The quarks are 4.1MeV d quarks, 5.7MeV d quarks and 130MeV s quarks.
Sigma ^- Rab mass energy + 4.1MeV the d quark + 5.7MeV the d quark + 130MeV of s quark sigma ^{- -} mass energy - ^- Mass Energy = sigma Rab mass energy = sigma of (4.1MeV the d quark +5 .7MeV d quark + 130MeV s quark) = 1119.449MeV-(4.1MeV + 5.7MeV + 130MeV) = 1119.449MeV-139.8MeV = 1057.649MeV = 1057.649 x 1.602 x 10 ^-19 J x 10 ⁶ = 1.694 x 10 ^-10 J
Sigma ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 1.694 × 10 -10 J) = 5.115 × 10 -14 m
Energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (5.115 x 10 ^-14 m) = 2.411 x 10 ^-28 J
Sigma ^- Rab electromagnetic number = sigma ^- Energy = 1.694 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(2.411 × 10 -28 J) =} 7.026 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution number of revolutions = 5.115 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ ) = 3.701 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.411 x 10 ^-28 J ÷ (4.34 x 10 ⁴ times) = 5.555 x 10 ^-33 J
Sigma ^- Rab orbit of ^{= 1.058 × 10 -10 m ÷ (} 5.115 × 10 -14 m) = 2.068 × 10 3 - orbit ÷ sigma Rab is possible with field A = the surface of the electronic Rab

This is shown in the table.
Σ ^- those constituting the Table 6

7). Σ ^- it is Σ ^- constituted by the love and 4.1MeV of the d quark and 5.7MeV of the d quark and 130MeV of s quark. How is it rotating?
Σ ^- the orbit of the Love is 5.115 × 10 ^-14 m.
The quark is rotating in this.
What is the trajectory of the 130MeV s quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (130 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (2.083 × 10 ^-11 J) = 3.699 × 10 ^-22 m
What is the orbit of a 5.7MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (5.7 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (9.131 × 10 ⁻¹³ J) = 8.438 × 10 ⁻²¹ m
What is the trajectory of the 4.1MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (4.1 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (6.568 × 10 ⁻¹³ J) = 1.173 × 10 ⁻²⁰ m


It is summarized in the table.
Sigma ^- Rab rotation trajectory and orbit the track table of orbital and 130 MeV of s Quark d quark orbital and 5.7MeV of d Quark 4.1MeV rotating therein 7

Sigma ^- the love and rotation trajectory of 3.701 × 10 ^-18 m, making the magnetic photons, are making photons of electrical and orbits of 5.115 × 10 ^-14 m.
The 130MeV s quark is rotating left in a 3.699 × 10 ^-22 m orbit. Outside that, the 5.7MeV d-quark is rotating left on an orbit of 8.438 × 10 ⁻²¹ m. In addition, the 4.1-MeV d-quark on the outside rotates leftward on a 1.173 × 10 ⁻²⁰ m orbit.

8). Ξ ^- the configuration of, Ξ ^- Love and the d quark of, and s quarks, is s quark. What is the structure?
.XI ^- mass energy is ^{1314.9MeV = 1314.9 × 1.602 × 10 -19} J × 10 6 = 2.106 × 10 -10 J.
The quarks are 5.7 MeV d quarks, 80 MeV s quarks and 130 MeV s quarks.
.XI ^- Mass Energy = .XI ^- Rab mass energy + 5.7MeV the d quark + 80 meV of s quark + 130MeV of s quark .XI ^- mass energy - ^- Mass Energy = .XI Rab (5.7MeV the d quark + 80 meV for s Quark + 130MeV s Quark) = 1314.9MeV- (5.7MeV + 80MeV + 130MeV) = 1314.9MeV-215.7MeV = 1099.2MeV = 1099.2 x 1.602 x 10 ^-19 J x 10 ⁶ = 1.761 x 10 ^-10 J
.XI ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 1.761 × 10 -10 J) = 4.920 × 10 -14 m
Energy of one photon generated by one revolution = 1.233 x 10 ^-41 Jm ÷ (4.920 x 10 ^-14 m) = 2.506 x 10 ^-28 J
.XI ^- Rab electromagnetic number = .XI ^- Energy = 1.761 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(2.506 × 10 -28 J) =} 7.027 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution of rotation = 4.920 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ times) = 3.560 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.506 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 5.774 x 10 ^-33 J
.XI ^- orbit ÷ .XI Rab is possible with field A = the surface of the electronic Love ^- Love orbit = 1.058 × 10 of ^{-10 m ÷ (4.920 × 10 -14} m) = 2.150 × 10 3

This is shown in the table.
Ξ ^- those constituting the table 8

9. Ξ ⁻ is composed of Ξ ⁻ love, 5.7 MeV d quark, 80 MeV s quark and 130 MeV s quark. How is it rotating?
Ξ ^- the orbit of the Love is 4.920 × 10 ^-14 m.
The quark is rotating in this.
What is the trajectory of the 80MeV s quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (80 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (1.282 × 10 ⁻¹¹ J) = 6.010 × 10 ⁻²² m

It is summarized in the table.
ラ ブ⁻ Rotating and revolving orbits, 5.7 MeV d-quark orbit, 80 MeV s-quark orbit and 130 MeV s-quark orbit rotating in it

.XI ^- Rab is rotation the trajectory of 3.560 × 10 ^-18 m, making the magnetic photons, and orbits of 4.920 × 10 ^-14 m, are making photons of electricity.
The 130MeV s quark rotates counterclockwise on a 3.699 × 10 ⁻²² m orbit. Outside that, the 80MeV s quark is rotating in a 6.010 × 10 ⁻²² m orbit. The outer 5.7MeV d-quark
It is turning left on an orbit of 8.438 × 10 ⁻²¹ m.

10. Ω ^- the configuration of, Ω ^- and Love and s quarks of, and s quarks, is s quark. What is the structure?
Omega ^- mass energy is ^{1672.45MeV = 1672.45 × 1.602 × 10 -19} J × 10 6 = 2.679 × 10 -10 J.
The quarks are 80MeV s quarks, 105MeV s quarks and 130MeV s quarks.
Omega ^- of Rab mass energy + 80 meV of s quark + 105MeV of s quark + 130MeV s quark Omega ^{- -} mass energy - ^- Mass Energy = Omega Rab (the s quark + 105MeV of 80 meV in the s quark + 130MeV mass energy = Omega of s quark) = 1672.45MeV- (80MeV + 105MeV + 130MeV) = 1672.45MeV-315MeV = 1357.45MeV = 1357.45 × 1.602 × 10 ^-19 J × 10 ⁶ = 2.175 × 10 ^-10 J
Omega ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 2.175 × 10 -10 J) = 3.984 × 10 -14 m
Energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (3.984 x 10 ^-14 m) = 3.095 x 10 ^-28 J
Omega ^- Rab electromagnetic number = Omega ^- Energy = 2.175 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(3.095 × 10 -28 J) =} 7.027 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution of rotation = 3.984 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ times) = 2.882 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 3.095 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 7.131 x 10 ^-33 J
Omega ^- Rab orbit of ^{= 1.058 × 10 -10 m ÷ (} 3.984 × 10 -14 m) = 2.656 × 10 3 - orbit ÷ Omega Rab is possible with field A = the surface of the electronic Rab

This is shown in the table.
Ω ^- those constituting the table 10

11. Ω ⁻ is composed of Ω ⁻ love, 80 MeV s quark, 105 MeV s quark and 130 MeV s quark. How is it rotating?
Ω ^- the orbit of the Love is 3.984 × 10 ^-14 m.
The quark is rotating in this.
What is the trajectory of the 105MeV s quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (105 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (1.682 × 10 ⁻¹¹ J) = 4.581 × 10 ⁻²² m

It is summarized in the table.
Omega ^- Rab rotation trajectory and orbit the track table of orbital and 130 MeV of s Quark s quark orbital and 105MeV of s Quark 80MeV to rotate therein 11

Omega ^- Rab is rotation the trajectory of 2.882 × 10 ^-18 m, making the magnetic photons, and orbits of 1.803 × 10 ^-13 m, are making photons of electricity.
The 130 MeV s quark rotates counterclockwise on a 3.699 × 10 ⁻²² m orbit. On the outside, the 105MeV s quark is rotating left about 4.581 × 10 ⁻²² m. Further outside, the 80MeV s quark is rotating left on a 6.010 × 10 ⁻²² m orbit.

12 What kind of particles are love?
・ Δ ⁻ (1232) Love Δ ⁻ (1232) Love Mass Energy = 1232MeV- (4.1MeV + 4.9MeV + 5.7MeV) = 1232MeV-14.7MeV = 1217.3MeV = 1217.3 × 1.602 × 10 ^-19 J × 10 ⁶ = 1.950 × 10 ^-10 J
The revolution trajectory of the lab of Δ ⁻ (1232) is 8.665 × 10 ⁻²⁴ Jm ÷ (1.950 × 10 ⁻¹⁰ J) = 4.444 × 10 ⁻¹⁴ m.
The energy of one electric photon generated per revolution is 1.233 × 10 ⁻⁴¹ Jm ÷ (4.444 × 10 ⁻¹⁴ m) = 2.775 × 10 ⁻²⁸ J.
Delta ^- Electromagnetic number Rab (1232) is, delta ^- (1232) Energy = 1.950 × 10 ^-10 J ÷ Love single photon mass energy ÷ electricity of ^{(2.775 × 10 -28 J) =} 7.027 × 10 ¹⁷ (pieces)
Magnetic photon rotation orbit = Electric photon rotation orbit x 3.14 ÷ 1 revolution rotation number = 4.444 x 10 ^-14 m x 3.14 ÷ (4.34 x 10 ⁴ times) = 3.215 x 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.775 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 6.394 x 10 ^-33 J
Δ ⁻ (1232) where the lab is formed A = revolution trajectory of the earth's electron lab ÷ Δ ⁻ (1232) lab's orbit = 1.058 × 10 ^-10 m ÷ (4.444 × 10 ^-14 m) = 2.381 × 10 ³
· Sigma ^- Love sigma ^- mass energy - ^- Rab mass energy = sigma of (s Quark d quark + 5.7MeV the d quark + 130MeV of 4.1MeV) = 1197.449MeV- (4.1MeV + 5.7MeV + 130MeV) = 1197.449MeV -139.8MeV = 1057.649MeV = 1057.649 × 1.602 × 10 ^-19 J × 10 ⁶ = 1.694 × 10 ^-10 J. This is 1.694 × 10 ⁻¹⁰ J ÷ (1.950 × 10 ⁻¹⁰ J) = 0.869 times the mass energy of Δ ⁻ (1232) lab.
Sigma ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 1.694 × 10 -10 J) = 5.115 × 10 -14 m. This is 5.115 × 10 ^-14 m ÷ (4.444 × 10 ^-14 m) = 1.151 times the revolution trajectory of the lab of Δ ⁻ (1232).
The energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (5.115 x 10 ^-14 m) = 2.411 x 10 ^-28 J. This is 2.411 × 10 ⁻²⁸ J ÷ (2.775 × 10 ⁻²⁸ J) = 0.869 times the energy of one electric photon generated by one revolution of the lab of Δ ⁻ (1232).
Sigma ^- Rab electromagnetic number = sigma ^- Energy = 1.694 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(2.411 × 10 -28 J) =} 7.026 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution number of revolutions = 5.115 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ ) = 3.701 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.411 x 10 ^-28 J ÷ (4.34 x 10 ⁴ times) = 5.555 x 10 ^-33 J
Sigma ^- Rab can be a field A = the surface of the electronic Rab orbit ÷ sigma ^- Rab orbit ^{= 1.058 × 10 -10 m ÷ (} 5.115 × 10 -14 m) = 2.068 × 10 3. This is 2.068 × 10 ³ ÷ (2.381 × 10 ³ ) = 0.869 times the love A of Δ ⁻ (1232).
· .XI ^- Love .XI ^- mass energy - ^- Rab mass energy = .XI of (s quark + 130MeV of s Quark d quark + 80 meV of 5.7MeV) = 1314.9MeV- (5.7MeV + 80MeV + 130MeV) = 1314.9MeV-215.7MeV = 1099.2 MeV = 1099.2 × 1.602 × 10 ⁻¹⁹ J × 10 ⁶ = 1.761 × 10 ⁻¹⁰ J. This is 1.761 × 10 ⁻¹⁰ J ÷ (1.950 × 10 ⁻¹⁰ J) = 0.903 times the mass energy of the lab of Δ ⁻ (1232).
.XI ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 1.761 × 10 -10 J) = 4.920 × 10 -14 m. This is 4.920 × 10 ^-14 m ÷ (4.444 × 10 ^-14 m) = 1.107 times the revolution trajectory of the lab of Δ ⁻ (1232).
The energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (4.920 x 10 ^-14 m) = 2.506 x 10 ^-28 J. This is 2.506 × 10 ⁻²⁸ J ÷ (2.775 × 10 ⁻²⁸ J) = 0.903 times the energy of one electric photon generated by one revolution of the lab of Δ ⁻ (1232).
.XI ^- Rab electromagnetic number = .XI ^- Energy = 1.761 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(2.506 × 10 -28 J) =} 7.027 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution of rotation = 4.920 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ times) = 3.560 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.506 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 5.774 x 10 ^-33 J
.XI ^- orbit ÷ .XI Rab is possible with field A = the surface of the electronic Rab ^- Rab orbit ^{= 1.058 × 10 -10 m ÷ (} 4.920 × 10 -14 m) = 2.150 × 10 3. This is 2.150 × 10 ³ ÷ (2.381 × 10 ³ ) = 0.903 times the love A of Δ ⁻ (1232).
· Ω ^- mass energy of - ^- of Love mass energy = Ω of ^- Love Ω of (s quark + 130MeV of s quark of s quark + 105MeV of 80MeV) = 1672.45MeV- (80MeV + 105MeV + 130MeV) = 1672.45MeV-315MeV = 1357.45 MeV = 1357.45 x 1.602 x 10 ^-19 J x 10 ⁶ = 2.175 x 10 ^-10 J. This is 2.175 × 10 ^-10 J ÷ (1.950 × 10 ^-10 J) = 1.115 times the mass energy of the lab of Δ ⁻ (1232).
Omega ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 2.175 × 10 -10 J) = 3.984 × 10 -14 m. This is 3.984 × 10 ^-14 m ÷ (4.444 × 10 ^-14 m) = 0.896 times the revolution trajectory of the lab of Δ ⁻ (1232).
The energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (3.984 x 10 ^-14 m) = 3.095 x 10 ^-28 J. This is 3.095 × 10 ⁻²⁸ J ÷ (2.775 × 10 ⁻²⁸ J) = 1.115 times the energy of one electric photon generated by one revolution of the lab of Δ ⁻ (1232).
Omega ^- Rab electromagnetic number = Omega ^- Energy = 2.175 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(3.095 × 10 -28 J) =} 7.027 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution of rotation = 3.984 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ times) = 2.882 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 3.095 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 7.131 x 10 ^-33 J
Ω ⁻ Love field A = Revolution trajectory of surface electron love ÷ Ω ⁻ Love revolution trajectory = 1.058 × 10 ⁻¹⁰ m ÷ (3.984 × 10 ⁻¹⁴ m) = 2.656 × 10 ³ . This is 2.656 × 10 ³ ÷ (2.381 × 10 ³ ) = 1.115 times the love A of Δ ⁻ (1232).

It is summarized in the table.
Love of Δ ⁻ (1232), Love of Σ ⁻ and Love of Ξ ⁻ and Love of Ω ⁻

What you can understand from this table
1． In the ^{sun, Δ - (1232), Σ} -, Ξ -, Ω - was possible.
2． The can was field ^{A, Δ - (1232),} Σ -, Ξ -, Ω - mass energy are different.
3． The thing that can be made in a high-energy field becomes high-energy electromagnetic, and becomes a high-energy particle. The orbit becomes smaller.

13. ^{Δ - (1232), Σ -} , Ξ -, Ω - the "unity of mass and electromagnetic mass particles" How in either.
"Unification of particle mass and electromagnetic mass"
Particle = electromagnetism of one bundle of electromagnetic waves = 7.028 × 10 ¹⁷ electromagnetism = particles of one electromagnetic bundle = mass of Love particles = E ÷ c ^{2 The} mass of the particles (particles of one electromagnetic bundle) is obtained.
The mass of the particles (particles of one electromagnetic bundle) is obtained by the following equation: mass of particles = 9.628 × 10 ⁻⁴¹ Jm ÷ orbital.
The mass of the particles (one electromagnetic bundle) is obtained by the following equation: mass of particles = 1.111 × 10 ⁻¹⁷ × particle energy.
The mass of one electromagnetic particle is obtained by the following equation: mass of one electromagnetic particle = mass of particle (mass of electromagnetic particle) ÷ electromagnetic number of one bundle.
The mass of one electromagnetic particle is obtained by the following equation: mass of one electromagnetic particle = 1.370 × 10 ⁻⁵⁸ Jm ÷ orbital.
Find the value of the energy of one electromagnetic particle ÷ the mass of one electromagnetic particle.

· Delta ^- Rab particles (1232) mass ^{= 1.950 × 10 -10 J ÷ (} 9 × 10 16) = 2.167 × 10 -27 Kg
Particle mass = 9.628 × 10 ^-41 Jm ÷ (4.444 × 10 ^-14 m) = 2.167 × 10 ^-27 Kg
Particle mass = 1.111 x 10 ^-17 x 1.950 x 10 ^-10 J = 2.166 x 10 ^-27 Kg
Mass of one electromagnetic particle = 2.167 × 10 ⁻²⁷ Kg ÷ (7.027 × 10 ¹⁷ particles) = 3.084 × 10 ⁻⁴⁵ Kg
Mass of one electromagnetic particle = 1.370 × 10 ⁻⁵⁸ Jm ÷ (4.444 × 10 ^-14 m) = 3.082 × 10 ^-45 Kg
Energy of one electromagnetic particle ÷ Mass of one electromagnetic particle = 2.775 × 10 ⁻²⁸ J ÷ (3.084 × 10 ⁻⁴⁵ Kg) = 8.998 × 10 ¹⁶
Sigma ^- mass of Rab particles ^{= 1.694 × 10 -10 J ÷ (} 9 × 10 16) = 1.882 × 10 -27 Kg
Particle mass = 9.628 × 10 ^-41 Jm ÷ (5.115 × 10 ^-14 m) = 1.882 × 10 ^-27 Kg
Particle mass = 1.111 x 10 ^-17 x 1.694 x 10 ^-10 J = 1.882 x 10 ^-27 Kg
Mass of one electromagnetic particle = 1.882 × 10 ^-27 Kg ÷ (7.026 × 10 ¹⁷ particles) = 2.679 × 10 ^-45 Kg
Mass of one electromagnetic particle = 1.370 x 10 ^-58 Jm ÷ (5.115 x 10 ^-14 m) = 2.678 x 10 ^-45 Kg
Energy of one electromagnetic particle ÷ Mass of one electromagnetic particle = 2.411 × 10 ^-28 J ÷ (2.679 × 10 ^-45 Kg) = 9.000 × 10 ¹⁶
· .XI ^- Rab particle mass ^{= 1.761 × 10 -10 J ÷ (} 9 × 10 16) = 1.957 × 10 -27 Kg
Particle mass = 9.628 × 10 ⁻⁴¹ Jm ÷ (4.920 × 10 ^-14 m) = 1.957 × 10 ⁻²⁷ Kg
Particle mass = 1.111 × 10 ^-17 × 1.761 × 10 ^-10 J = 1.957 × 10 ^-27 Kg
Mass of one electromagnetic particle = 1.957 × 10 ^-27 Kg ÷ (7.027 × 10 ¹⁷ particles) = 2.785 × 10 ^-45 Kg
Mass of one electromagnetic particle = 1.370 x 10 ^-58 Jm ÷ (4.920 x 10 ^-14 m) = 2.785 x 10 ^-45 Kg
Energy of one electromagnetic particle ÷ Mass of one electromagnetic particle = 2.506 × 10 ⁻²⁸ J ÷ (2.785 × 10 ⁻⁴⁵ Kg) = 8.998 × 10 ¹⁶
· Omega ^- mass of Rab particles ^{= 2.175 × 10 -10 J ÷ (} 9 × 10 16) = 2.417 × 10 -27 Kg
Particle mass = 9.628 × 10 ⁻⁴¹ Jm ÷ (3.984 × 10 ^-14 m) = 2.417 × 10 ⁻²⁷ Kg
Particle mass = 1.111 × 10 ^-17 × 2.175 × 10 ^-10 J = 2.416 × 10 ^-27 Kg
Mass of one electromagnetic particle = 2.417 x 10 ^-27 Kg ÷ (7.027 x 10 ¹⁷ ) = 3.440 x 10 ^-45 Kg
Mass of one electromagnetic particle = 1.370 × 10 ⁻⁵⁸ Jm ÷ (3.984 × 10 ^-14 m) = 3.439 × 10 ⁻⁴⁵ Kg
Energy of one electromagnetic particle ÷ Mass of one electromagnetic particle = 3.095 × 10 ⁻²⁸ J ÷ (3.440 × 10 ⁻⁴⁵ Kg) = 8.997 × 10 ¹⁶

This is shown in the table.
The mass energy of the lab, the orbit of the lab, the electromagnetic number of the lab, the energy of one photon generated by the lab in one revolution and the mass of the particle = E ÷ c ² and the mass of the particle = 9.628 × 10 ^-41 Jm Orbit, particle mass = 1.111 × 10 ⁻¹⁷ × particle energy, one electromagnetic particle mass = particle mass ÷ electromagnetic number, and one electromagnetic particle mass = 1.370 × 10 ⁻⁵⁸ Jm ÷ orbital And the energy of one electromagnetic particle ÷ the mass of one electromagnetic particle
Table 13

Things that can be understood by this
1． The mass of the lab is 1.8 ~ 2.4 × 10 ⁻²⁷ Kg.
2． The mass of one lab electromagnetic is 2.6 ~ 3.4 × 10 ⁻⁴⁵ Kg.
3． "Delta ^- (1232) Love and sigma ^- Love and .XI ^- Love and Omega ^- Rab and mass of the particle delta ^- (1232) Love and sigma ^- Love and .XI ^- Love and Omega ^- Rab The "unification of electromagnetic mass" is established.

14 What is the mass energy of a quark rotating in the lab?
Understand what percentage of quark's mass energy is that of love.
Delta ^- (1232) Love and Σ of ^- Rab and .XI ^- Love and Ω of ^- rotating through the Love, to calculate the mass energy × 100, the value of the mass energy ÷ Rab quark.

It is summarized in the table.
What percentage of the mass energy of the quark rotating in the lab of Δ ⁻ (1232), Σ ⁻ lab and Ξ ⁻ and Ω ⁻


What you can understand from this table
1. The mass energy of a quark rotating in the smallest orbit is 0.47% to 12.3% of the mass energy of the lab.
The mass energy of the quark rotating in the second smallest orbit is 0.40% to 7.74% of the mass energy of the lab.
The mass energy of the quark rotating in the third smallest orbit is 0.33% to 5.89% of the mass energy of the lab.

15. Delta ^- (1232) Love and sigma ^- Love and .XI ^- Love and Omega ^- Is orbit of quark which rotates in the Love is what is.
The table shows the orbit of the quarks rotating in the lab.

It is summarized in the table.
Track 15 of a quark rotating in the love

This is illustrated.

  Knowing elementary particles is knowing atoms and elements, which is useful for industrial development.

1 Δ ^- Love of the (1232)
2 delta ^- Love orbit of (1232) is 4.444 × 10 ^-14 m
3 Σ ^- of Love
4 sigma ^- the orbit of Rab 5.115 × 10 ^-14 m
5 Ξ ^- no love
6 .XI ^- the orbit of Rab 4.920 × 10 ^-14 m
7 Ω ^- of Love
8 Ω ^- the orbit of Love 3.984 × 10 ^-14 m
9 d quarks of 5.7 MeV
10 5.7 MeV d quark rotates left on orbit of 8.438 × 10 ⁻²¹ m 11 4.9 MeV d quark
12 4.9 MeV d-quark rotates left on orbit of 9.815 × 10 ⁻²¹ m
13 4.1MeV d-quark
14 4.1 MeV d-quark turns left on orbit of 1.173 × 10 ⁻²⁰ m
15 130MeV s quark
16 130MeV s quark rotates 3.699 × 10 ^-22 m orbit left 17 80 MeV s quark
18 80MeV s quark rotates left on orbit of 6.010 × 10 ⁻²² m
19 105MeV s quark
20 105MeV s quark turns left on orbit of 4.581 × 10 ⁻²² m

Claims (15)

Δ ^- the configuration of the (1232) is, Δ ^- (1232) and Love and the d quark of, and the d quark, is the d quark. What is the structure?
Since the mass energy of Δ ⁻ (1232) is 1231 MeV to 1233 MeV, it is an intermediate value, 1232 MeV = 1232 × 1.602 × 10 ^-19 J × 10 ⁶ = 1.974 × 10 ^-10 J And
Since the d quark is 4.1MeV to 5.7MeV, it is assumed to be 4.1MeV d quark, 4.9MeV d quark and 5.7MeV d quark.
Δ ⁻ Mass energy of (1232) = Δ ⁻ Mass energy of lab of (1232) + 4.1MeV d quark + 4.9MeV d quark + 5.7MeV d quark Δ ⁻ Mass energy of lab of (1232) = Δ ⁻ Mass energy of (1232)-(4.1MeV d quark + 4.9MeV d quark + 5.7MeV d quark)
Δ ⁻ Mass energy of (1232) lab = 1232MeV- (4.1MeV + 4.9MeV + 5.7MeV) = 1232MeV-14.7MeV = 1217.3MeV = 1217.3 × 1.602 × 10 ^-19 J × 10 ⁶ = 1.950 × 10 ^-10 J
The revolution trajectory of the lab of Δ ⁻ (1232) is 8.665 × 10 ⁻²⁴ Jm ÷ (1.950 × 10 ⁻¹⁰ J) = 4.444 × 10 ⁻¹⁴ m.
The energy of one electric photon generated per revolution is 1.233 × 10 ⁻⁴¹ Jm ÷ (4.444 × 10 ⁻¹⁴ m) = 2.775 × 10 ⁻²⁸ J.
Delta ^- Electromagnetic number Rab (1232) is, delta ^- (1232) Energy = 1.950 × 10 ^-10 J ÷ Love single photon mass energy ÷ electricity of ^{(2.775 × 10 -28 J) =} 7.027 × 10 ¹⁷ (pieces)
Magnetic photon rotation orbit = Electric photon rotation orbit x 3.14 ÷ 1 revolution rotation number = 4.444 x 10 ^-14 m x 3.14 ÷ (4.34 x 10 ⁴ times) = 3.215 x 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.775 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 6.394 x 10 ^-33 J
Δ ⁻ (1232) where the lab is formed A = revolution trajectory of the earth's electron lab ÷ Δ ⁻ (1232) lab's orbit = 1.058 × 10 ^-10 m ÷ (4.444 × 10 ^-14 m) = 2.381 × 10 ³

This is shown in the table.
Table 16 constituting Δ ⁻ (1232)
Δ ⁻ (1232) is composed of a love of Δ ⁻ (1232), a d-quark of 4.1 MeV, a d-quark of 4.9 MeV, and a d-quark of 5.7 MeV. How is it rotating? 1
The revolution trajectory of Δ ⁻ (1232) lab is 4.444 × 10 ^-14 m.
Around this, d-quarks are rotating.
What is the trajectory of the 4.1MeV d-quark?
Orbit = 2.312 × 10 ⁻²⁴ Jm ÷ Quark energy = 2.312 × 10 ⁻²⁴ Jm ÷ (4.1 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 2.312 × 10 ⁻²⁴ Jm ÷ (6.568 × 10 ^-13 J) = 3.520 × 10 ^-12 m
The orbit of 4.1MeV d-quark is 3.520 × 10 ^-12 m.
4.9 What is the orbit of the MeV d-quark?
Orbit = 2.312 × 10 ⁻²⁴ Jm ÷ Quark energy = 2.312 × 10 ⁻²⁴ Jm ÷ (4.9 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 2.312 × 10 ⁻²⁴ Jm ÷ (7.850 × 10 ^-13 J) = 2.945 × 10 ^-12 m
The orbit of a 4.9MeV d-quark is 2.945 × 10 ^-12 m.
What is the orbit of a 5.7 MeV d-quark?
Orbit = 2.312 × 10 ⁻²⁴ Jm ÷ Quark energy = 2.312 × 10 ⁻²⁴ Jm ÷ (5.7 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 2.312 × 10 ⁻²⁴ Jm ÷ (9.131 × 10 ^-13 J) = 2.532 × 10 ^-12 m

It is summarized in the table.
Rotating and revolving orbits of Δ ⁻ (1232) lab, 4.1MeV d-quark orbit, 4.9MeV d-quark orbit and 5.7MeV d-quark orbit rotating around it

Δ ⁻ (1232) revolves around a 4.444 × 10 ⁻¹⁴ m orbit while the love of Δ ⁻ (1232) rotates around the orbit of 3.215 × 10 ⁻¹⁸ m.
The 5.7MeV d-quark rotates counterclockwise on the outer 2.532 × 10 ^-12 m orbit. Furthermore, the 4.9MeV d-quark is rotating counterclockwise on the outer 2.945 × 10 ^-12 m orbit. The 4.1MeV d-quark rotates counterclockwise on the outermost orbit of 3.520 × 10 ^-12 m. Calculation of orbit and energy delta ^- (1232) Rab is rotation the trajectory of 3.215 × 10 ^-18 m, the magnetic photon one energy making is 6.394 × 10 ^-33 J. Since one revolution is 4.34 × 10 ⁴ rotations, the energy of a magnetic photon created by one revolution is 6.394 × 10 ⁻³³ J × 4.34 × 10 ⁴ rotations = 2.775 × 10 ⁻²⁸ J.
At the same time, the Δ ⁻ (1232) lab revolves around an orbit of 4.444 × 10 ^-14 m, creating one photon of 2.775 × 10 ⁻²⁸ J in one revolution.
The energy of magnetic photons created by the lab of Δ ⁻ (1232) is equal to the energy of electric photons.
Photons and magnetic photons of this electricity is in orbit 2.532 × 10 ^-12 m, are made to d quark of 5.7MeV become a 6.249 × 10 ⁸ cells bound 1 mass.
These photons are coupled with magnetic photons, and the total number of magnetic photons is the number of electrical photons x 4.34 x 10 ⁴ rotations = 6.249 x 10 ⁸ x 4.34 x 10 ⁴ rotations = 2.712 x 10 ¹³ pieces.
The energy of one electric photon is 1.233 × 10 ^-41 Jm ÷ (2.532 × 10 ^-12 m) = 4.870 × 10 ^-30 J.
The quark is a collection of 6.249 × 10 ⁸ electromagnetics in one lump, so this energy is 6.249 × 10 ⁸ × 4.870 × 10 ^-30 J = 3.043 × 10 ^-21 J.
5.7MeV = 5.7 × 1.602 × 10 ^-19 J × 10 ⁶ = 9.131 × 10 ^-13 J
How many 5.7 MeV is the energy of an electric photon?
9.131 × 10 ^-13 J ÷ (4.870 × 10 ^-30 J) = 1.875 × 10 ¹⁷
5.7MeV is the energy of 1.875 × 10 ¹⁷ electrical photons.
This is a multiple of 6.249 × 10 ⁸ pieces.
1.875 × 10 ¹⁷ pieces ÷ (6.249 × 10 ⁸ pieces) = 3.000 × 10 ⁸ times This is 6.249 × 10 ⁸ pieces 3.000 × 10 ⁸ times.
That is, when the orbit of an electric photon is 2.532 × 10 ^-12 m, the energy of one electric photon is 4.870 × 10 ^-30 J, and the energy gathered by 6.249 × 10 ⁸ is 3.043 × 10 ^-21 J .
This energy is one of 3.000 × 10 ⁸ minutes of 5.7MeV.
Thus since the cause was a surface energy 5.7MeV of (3 × 10 ⁸⁾ content of 1 energy ^{= 9.131 × 10 -13 J ÷ (} 3 × 10 8) = 3.044 × 10 -21 J, and Because.
Then, the energy of one electromagnetic is 3.044 × 10 ^-21 J ÷ (6.249 × 10 ⁸ pieces) = 4.871 × 10 ⁻³⁰ J, and this orbit is 1.233 × 10 ⁻⁴¹ Jm ÷ (4.871 × 10 ⁻³⁰ J ) = 2.531 × 10 ⁻¹² m.
The energy of the quark in Δ ⁻ (1232) is 5.7 MeV, so this is the electromagnetic orbit.
That is, the energy of one electromagnetic is 5.7MeV ÷ (6.249 × 10 ⁸ pieces) = 9.131 × 10 ⁻¹³ J ÷ (6.249 × 10 ⁸ pieces) = 1.461 × 10 ⁻²¹ J. The electromagnetic orbit is 1.233 × 10 ⁻⁴¹ Jm ÷ (1.461 × 10 ⁻²¹ J) = 8.439 × 10 ⁻²¹ m.
This is data in the high energy accelerator of Japanese Patent Application No. 09-09333 “Quark 2” submitted on May 10, 2016.
So we have to correct the issues, the central ones and the quarks that have been submitted so far.
This correction will be made in the next patent application.

This is shown in the table.
Data on the surface and surface of the high energy accelerator of Japanese Patent Application No. 2016-094933 “Quark 2” submitted on May 10, 2016
For 5.7 MeV d-quark Table 18

The energy of the quark on the surface is 9.131 × 10 ⁻¹³ J ÷ (3 × 10 ⁸ ) = 3.044 × 10 ⁻²¹ J.
So the orbit is 2.531 × 10 ⁻¹² m.
However, the energy of d-quark of 5.7MeV on the surface is 5.7MeV = 9.131 × 10 ⁻¹³ J.
The orbit is 8.439 × 10 ⁻²¹ m. How should the quark trajectory be calculated?
The orbit of the electron lab or proton lab was obtained by the formula: orbital = 8.665 x 10 ^-24 Jm ÷ energy.
In the case of one electromagnet, it was obtained by the equation: orbital = 1.233 × 10 ⁻⁴¹ Jm ÷ energy of one electromagnet.
And, in “Claim 15” of Japanese Patent Application No. 2016-114926 “Yoko, Δ ⁺ (1232), Σ ⁺ , Λ ⁺ _c ” filed on June 9, 2016, it was written as follows.
(15. Particle orbital energy is 8.665 × 10 ⁻²⁴ Jm. Electromagnetic orbital energy is 1.233 × 10 ⁻⁴¹ Jm. What does this mean?
How many times the orbital energy of particles is the electromagnetic orbital energy?
Particle orbital energy ÷ Electromagnetic orbital energy = 8.665 × 10 ⁻²⁴ Jm ÷ (1.233 × 10 ⁻⁴¹ Jm) = 7.028 × 10 ¹⁷
The orbital energy of particles is 7.028 × 10 ¹⁷ times the electromagnetic orbital energy.
This means that 7.028 × 10 ¹⁷ electromagnets gather and form particles.
This is orbital energy = orbital mass energy.
From "Unification of particle mass and electromagnetic mass"
Because energy = mass energy.
Orbital energy of particles = electromagnetic orbital energy x 7.028 x 10 ¹⁷
Orbital mass energy of particles = electromagnetic orbital mass energy x 7.028 x 10 ¹⁷
(This indicates that 7.028 × 10 ¹⁷ electromagnetism gathers into particles)
From the above, the quark is a mass of 6.249 × 10 ⁸ electromagnetics gathered, so the orbital energy of the quark is 1 electromagnetic orbital energy × 6.249 × 10 ⁸ = 1.233 × 10 ⁻⁴¹ Jm It is considered that × 6.249 × 10 ⁸ = 7.705 × 10 ⁻³³ Jm.
Therefore, the orbit of a 5.7MeV quark is orbit = 7.705 × 10 ⁻³³ Jm ÷ 5.7MeV = 7.705 × 10 ⁻³³ Jm ÷ (9.131 × 10 ⁻¹³ J) = 8.438 × 10 ⁻²¹ m.
This data is the same as the data filed on May 10, 2016 in the high energy accelerator of Japanese Patent Application No. 2016-094933 “Quark 2”.
Therefore, the orbital energy of quarks is 7.705 × 10 ⁻³³ Jm.

This is noted in the table.
Orbital energy table 19
Δ ⁻ (1232) is composed of a love of Δ ⁻ (1232), a d-quark of 4.1 MeV, a d-quark of 4.9 MeV, and a d-quark of 5.7 MeV. How is it rotating? 2
The revolution trajectory of Δ ⁻ (1232) lab is 4.444 × 10 ^-14 m.
The quark is rotating in this.
What is the orbit of a 5.7MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (5.7 × 1.602 × 10 ⁻¹⁹ J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (9.131 × 10 ⁻¹³ J) = 8.438 × 10 ⁻²¹ m
What is the orbit of a 4.9MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (4.9 × 1.602 × 10 ⁻¹⁹ J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (7.850 × 10 ⁻¹³ J) = 9.815 × 10 ⁻²¹ m
What is the trajectory of the 4.1MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (4.1 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (6.568 × 10 ⁻¹³ J) = 1.173 × 10 ⁻²⁰ m

It is summarized in the table.
Rotation and revolution orbits of the lab of Δ ⁻ (1232), 4.1MeV d-quark orbit, 4.9MeV d-quark orbit, and 5.7MeV d-quark orbit rotating in the table 20

The Δ ⁻ (1232) lab rotates on a 3.215 × 10 ^-18 m orbit, creating a magnetic photon, and revolving on a 4.444 × 10 ^-14 m orbit, creating an electric photon.
The 5.7MeV d quark rotates left on the orbit of 8.438 × 10 ⁻²¹ m, the outer 4.9 MeV d quark rotates left on the orbit of 9.815 × 10 ⁻²¹ m, and the outer 4.1 MeV. The d-quark is rotating left about 1.173 × 10 ⁻²⁰ m. Σ ^- the configuration of, Δ ^- (1232) and Love and the d quark of, and the d quark, is s quark. What is the structure?
Sigma ^- mass energy, 1197.449MeV = 1197.449 × 1.602 × 10 -19 J × 10 6 = 1.918 × 10 -10 J is.
The quarks are 4.1MeV d quarks, 5.7MeV d quarks and 130MeV s quarks.
Sigma ^- Rab mass energy + 4.1MeV the d quark + 5.7MeV the d quark + 130MeV of s quark sigma ^{- -} mass energy - ^- Mass Energy = sigma Rab mass energy = sigma of (4.1MeV the d quark +5 .7MeV d quark + 130MeV s quark) = 1119.449MeV-(4.1MeV + 5.7MeV + 130MeV) = 1119.449MeV-139.8MeV = 1057.649MeV = 1057.649 x 1.602 x 10 ^-19 J x 10 ⁶ = 1.694 x 10 ^-10 J
Sigma ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 1.694 × 10 -10 J) = 5.115 × 10 -14 m
Energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (5.115 x 10 ^-14 m) = 2.411 x 10 ^-28 J
Sigma ^- Rab electromagnetic number = sigma ^- Energy = 1.694 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(2.411 × 10 -28 J) =} 7.026 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution number of revolutions = 5.115 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ ) = 3.701 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.411 x 10 ^-28 J ÷ (4.34 x 10 ⁴ times) = 5.555 x 10 ^-33 J
Sigma ^- Rab orbit of ^{= 1.058 × 10 -10 m ÷ (} 5.115 × 10 -14 m) = 2.068 × 10 3 - orbit ÷ sigma Rab is possible with field A = the surface of the electronic Rab

This is shown in the table.
Sigma ^- those constituting the table 21
Σ ^- it is Σ ^- constituted by the love and 4.1MeV of the d quark and 5.7MeV of the d quark and 130MeV of s quark. How is it rotating?
Σ ^- the orbit of the Love is 5.115 × 10 ^-14 m.
The quark is rotating in this.
What is the trajectory of the 130MeV s quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (130 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (2.083 × 10 ^-11 J) = 3.699 × 10 ^-22 m
What is the orbit of a 5.7MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (5.7 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (9.131 × 10 ⁻¹³ J) = 8.438 × 10 ⁻²¹ m
What is the trajectory of the 4.1MeV d-quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (4.1 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (6.568 × 10 ⁻¹³ J) = 1.173 × 10 ⁻²⁰ m

It is summarized in the table.
Sigma ^- Rab rotation orbit with orbital table orbit with orbital and 130 MeV of s Quark d quark orbital and 5.7MeV of d Quark 4.1MeV rotating therein 22

Sigma ^- the love and rotation trajectory of 3.701 × 10 ^-18 m, making the magnetic photons, are making photons of electrical and orbits of 5.115 × 10 ^-14 m.
The 130MeV s quark is rotating left in a 3.699 × 10 ^-22 m orbit. Outside that, the 5.7MeV d-quark is rotating left on an orbit of 8.438 × 10 ⁻²¹ m. In addition, the 4.1-MeV d-quark on the outside rotates leftward on a 1.173 × 10 ⁻²⁰ m orbit. Ξ ^- the configuration of, Ξ ^- Love and the d quark of, and s quarks, is s quark. What is the structure?
.XI ^- mass energy is ^{1314.9MeV = 1314.9 × 1.602 × 10 -19} J × 10 6 = 2.106 × 10 -10 J.
The quarks are 5.7 MeV d quarks, 80 MeV s quarks and 130 MeV s quarks.
.XI ^- Mass Energy = .XI ^- Rab mass energy + 5.7MeV the d quark + 80 meV of s quark + 130MeV of s quark .XI ^- mass energy - ^- Mass Energy = .XI Rab (5.7MeV the d quark + 80 meV for s Quark + 130MeV s Quark) = 1314.9MeV- (5.7MeV + 80MeV + 130MeV) = 1314.9MeV-215.7MeV = 1099.2MeV = 1099.2 x 1.602 x 10 ^-19 J x 10 ⁶ = 1.761 x 10 ^-10 J
.XI ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 1.761 × 10 -10 J) = 4.920 × 10 -14 m
Energy of one photon generated by one revolution = 1.233 x 10 ^-41 Jm ÷ (4.920 x 10 ^-14 m) = 2.506 x 10 ^-28 J
.XI ^- Rab electromagnetic number = .XI ^- Energy = 1.761 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(2.506 × 10 -28 J) =} 7.027 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution of rotation = 4.920 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ times) = 3.560 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.506 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 5.774 x 10 ^-33 J
.XI ^- orbit ÷ .XI Rab is possible with field A = the surface of the electronic Love ^- Love orbit = 1.058 × 10 of ^{-10 m ÷ (4.920 × 10 -14} m) = 2.150 × 10 3

This is shown in the table.
Ξ ^- those constituting the table 23
Ξ ⁻ is composed of Ξ ⁻ love, 5.7 MeV d quark, 80 MeV s quark and 130 MeV s quark. How is it rotating?
Ξ ^- the orbit of the Love is 4.920 × 10 ^-14 m.
The quark is rotating in this.
What is the trajectory of the 80MeV s quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (80 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (1.282 × 10 ⁻¹¹ J) = 6.010 × 10 ⁻²² m

It is summarized in the table.
.XI ^- Rab rotation trajectory and orbit the track table of orbital and 130 MeV of s Quark s quark orbital and 80MeV the d quark of 5.7MeV rotating therein 24

.XI ^- Rab is rotation the trajectory of 3.560 × 10 ^-18 m, making the magnetic photons, and orbits of 4.920 × 10 ^-14 m, are making photons of electricity.
The 130MeV s quark rotates counterclockwise on a 3.699 × 10 ⁻²² m orbit. Outside that, the 80MeV s quark is rotating in a 6.010 × 10 ⁻²² m orbit. The outer 5.7MeV d-quark
It is turning left on an orbit of 8.438 × 10 ⁻²¹ m. Ω ^- the configuration of, Ω ^- and Love and s quarks of, and s quarks, is s quark. What is the structure?
Omega ^- mass energy is ^{1672.45MeV = 1672.45 × 1.602 × 10 -19} J × 10 6 = 2.679 × 10 -10 J.
The quarks are 80MeV s quarks, 105MeV s quarks and 130MeV s quarks.
Omega ^- of Rab mass energy + 80 meV of s quark + 105MeV of s quark + 130MeV s quark Omega ^{- -} mass energy - ^- Mass Energy = Omega Rab (the s quark + 105MeV of 80 meV in the s quark + 130MeV mass energy = Omega of s quark) = 1672.45MeV- (80MeV + 105MeV + 130MeV) = 1672.45MeV-315MeV = 1357.45MeV = 1357.45 × 1.602 × 10 ^-19 J × 10 ⁶ = 2.175 × 10 ^-10 J
Omega ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 2.175 × 10 -10 J) = 3.984 × 10 -14 m
Energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (3.984 x 10 ^-14 m) = 3.095 x 10 ^-28 J
Omega ^- Rab electromagnetic number = Omega ^- Energy = 2.175 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(3.095 × 10 -28 J) =} 7.027 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution of rotation = 3.984 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ times) = 2.882 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 3.095 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 7.131 x 10 ^-33 J
Omega ^- Rab orbit of ^{= 1.058 × 10 -10 m ÷ (} 3.984 × 10 -14 m) = 2.656 × 10 3 - orbit ÷ Omega Rab is possible with field A = the surface of the electronic Rab

This is shown in the table.
Ω ^- those constituting the table 25
Ω ⁻ is composed of Ω ⁻ love, 80 MeV s quark, 105 MeV s quark and 130 MeV s quark. How is it rotating?
Ω ^- the orbit of the Love is 3.984 × 10 ^-14 m.
The quark is rotating in this.
What is the trajectory of the 105MeV s quark?
Orbit = 7.705 × 10 ⁻³³ Jm ÷ Quark energy = 7.705 × 10 ⁻³³ Jm ÷ (105 × 1.602 × 10 ^-19 J × 10 ⁶ ) = 7.705 × 10 ⁻³³ Jm ÷ (1.682 × 10 ⁻¹¹ J) = 4.581 × 10 ⁻²² m

It is summarized in the table.
Omega ^- Rab rotation trajectory and orbit the track table of orbital and 130 MeV of s Quark s quark orbital and 105MeV of s Quark 80MeV to rotate therein 26

Omega ^- Rab is rotation the trajectory of 2.882 × 10 ^-18 m, making the magnetic photons, and orbits of 1.803 × 10 ^-13 m, are making photons of electricity.
The 130 MeV s quark rotates counterclockwise on a 3.699 × 10 ⁻²² m orbit. On the outside, the 105MeV s quark is rotating left about 4.581 × 10 ⁻²² m. Further outside, the 80MeV s quark is rotating left on a 6.010 × 10 ⁻²² m orbit. What kind of particles are love?
・ Δ ⁻ (1232) Love Δ ⁻ (1232) Love Mass Energy = 1232MeV- (4.1MeV + 4.9MeV + 5.7MeV) = 1232MeV-14.7MeV = 1217.3MeV = 1217.3 × 1.602 × 10 ^-19 J × 10 ⁶ = 1.950 × 10 ^-10 J
The revolution trajectory of the lab of Δ ⁻ (1232) is 8.665 × 10 ⁻²⁴ Jm ÷ (1.950 × 10 ⁻¹⁰ J) = 4.444 × 10 ⁻¹⁴ m.
The energy of one electric photon generated per revolution is 1.233 × 10 ⁻⁴¹ Jm ÷ (4.444 × 10 ⁻¹⁴ m) = 2.775 × 10 ⁻²⁸ J.
Delta ^- Electromagnetic number Rab (1232) is, delta ^- (1232) Energy = 1.950 × 10 ^-10 J ÷ Love single photon mass energy ÷ electricity of ^{(2.775 × 10 -28 J) =} 7.027 × 10 ¹⁷ (pieces)
Magnetic photon rotation orbit = Electric photon rotation orbit x 3.14 ÷ 1 revolution rotation number = 4.444 x 10 ^-14 m x 3.14 ÷ (4.34 x 10 ⁴ times) = 3.215 x 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.775 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 6.394 x 10 ^-33 J
Δ ⁻ (1232) where the lab is formed A = revolution trajectory of the earth's electron lab ÷ Δ ⁻ (1232) lab's orbit = 1.058 × 10 ^-10 m ÷ (4.444 × 10 ^-14 m) = 2.381 × 10 ³
· Sigma ^- Love sigma ^- mass energy - ^- Rab mass energy = sigma of (s Quark d quark + 5.7MeV the d quark + 130MeV of 4.1MeV) = 1197.449MeV- (4.1MeV + 5.7MeV + 130MeV) = 1197.449MeV -139.8MeV = 1057.649MeV = 1057.649 × 1.602 × 10 ^-19 J × 10 ⁶ = 1.694 × 10 ^-10 J. This is 1.694 × 10 ⁻¹⁰ J ÷ (1.950 × 10 ⁻¹⁰ J) = 0.869 times the mass energy of Δ ⁻ (1232) lab.
Sigma ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 1.694 × 10 -10 J) = 5.115 × 10 -14 m. This is 5.115 × 10 ^-14 m ÷ (4.444 × 10 ^-14 m) = 1.151 times the revolution trajectory of the lab of Δ ⁻ (1232).
The energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (5.115 x 10 ^-14 m) = 2.411 x 10 ^-28 J. This is 2.411 × 10 ⁻²⁸ J ÷ (2.775 × 10 ⁻²⁸ J) = 0.869 times the energy of one electric photon generated by one revolution of the lab of Δ ⁻ (1232).
Sigma ^- Rab electromagnetic number = sigma ^- Energy = 1.694 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(2.411 × 10 -28 J) =} 7.026 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution number of revolutions = 5.115 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ ) = 3.701 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.411 x 10 ^-28 J ÷ (4.34 x 10 ⁴ times) = 5.555 x 10 ^-33 J
Sigma ^- Rab can be a field A = the surface of the electronic Rab orbit ÷ sigma ^- Rab orbit ^{= 1.058 × 10 -10 m ÷ (} 5.115 × 10 -14 m) = 2.068 × 10 3. This is 2.068 × 10 ³ ÷ (2.381 × 10 ³ ) = 0.869 times the love A of Δ ⁻ (1232).
· .XI ^- Love .XI ^- mass energy - ^- Rab mass energy = .XI of (s quark + 130MeV of s Quark d quark + 80 meV of 5.7MeV) = 1314.9MeV- (5.7MeV + 80MeV + 130MeV) = 1314.9MeV-215.7MeV = 1099.2 MeV = 1099.2 × 1.602 × 10 ⁻¹⁹ J × 10 ⁶ = 1.761 × 10 ⁻¹⁰ J. This is 1.761 × 10 ⁻¹⁰ J ÷ (1.950 × 10 ⁻¹⁰ J) = 0.903 times the mass energy of the lab of Δ ⁻ (1232).
.XI ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 1.761 × 10 -10 J) = 4.920 × 10 -14 m. This is 4.920 × 10 ^-14 m ÷ (4.444 × 10 ^-14 m) = 1.107 times the revolution trajectory of the lab of Δ ⁻ (1232).
The energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (4.920 x 10 ^-14 m) = 2.506 x 10 ^-28 J. This is 2.506 × 10 ⁻²⁸ J ÷ (2.775 × 10 ⁻²⁸ J) = 0.903 times the energy of one electric photon generated by one revolution of the lab of Δ ⁻ (1232).
.XI ^- Rab electromagnetic number = .XI ^- Energy = 1.761 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(2.506 × 10 -28 J) =} 7.027 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution of rotation = 4.920 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ times) = 3.560 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 2.506 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 5.774 x 10 ^-33 J
.XI ^- orbit ÷ .XI Rab is possible with field A = the surface of the electronic Rab ^- Rab orbit ^{= 1.058 × 10 -10 m ÷ (} 4.920 × 10 -14 m) = 2.150 × 10 3. This is 2.150 × 10 ³ ÷ (2.381 × 10 ³ ) = 0.903 times the love A of Δ ⁻ (1232).
· Ω ^- mass energy of - ^- of Love mass energy = Ω of ^- Love Ω of (s quark + 130MeV of s quark of s quark + 105MeV of 80MeV) = 1672.45MeV- (80MeV + 105MeV + 130MeV) = 1672.45MeV-315MeV = 1357.45 MeV = 1357.45 x 1.602 x 10 ^-19 J x 10 ⁶ = 2.175 x 10 ^-10 J. This is 2.175 × 10 ^-10 J ÷ (1.950 × 10 ^-10 J) = 1.115 times the mass energy of the lab of Δ ⁻ (1232).
Omega ^- Rab orbit of ^{= 8.665 × 10 -24 Jm ÷ (} 2.175 × 10 -10 J) = 3.984 × 10 -14 m. This is 3.984 × 10 ^-14 m ÷ (4.444 × 10 ^-14 m) = 0.896 times the revolution trajectory of the lab of Δ ⁻ (1232).
The energy of one electric photon generated per revolution = 1.233 x 10 ^-41 Jm ÷ (3.984 x 10 ^-14 m) = 3.095 x 10 ^-28 J. This is 3.095 × 10 ⁻²⁸ J ÷ (2.775 × 10 ⁻²⁸ J) = 1.115 times the energy of one electric photon generated by one revolution of the lab of Δ ⁻ (1232).
Omega ^- Rab electromagnetic number = Omega ^- Energy = 2.175 × 10 ^-10 J ÷ Rab mass energy ÷ electric photon one ^{(3.095 × 10 -28 J) =} 7.027 × 10 17 ( pieces)
Magnetic photon rotation orbit = Electric photon orbit × 3.14 ÷ 1 revolution of rotation = 3.984 × 10 ^-14 m × 3.14 ÷ (4.34 × 10 ⁴ times) = 2.882 × 10 ^-18 m
Energy of one magnetic photon = Energy of one electric photon / Number of revolutions per revolution = 3.095 x 10 ^-28 J / (4.34 x 10 ⁴ times) = 7.131 x 10 ^-33 J
Ω ⁻ Love field A = Revolution trajectory of surface electron love ÷ Ω ⁻ Love revolution trajectory = 1.058 × 10 ⁻¹⁰ m ÷ (3.984 × 10 ⁻¹⁴ m) = 2.656 × 10 ³ . This is 2.656 × 10 ³ ÷ (2.381 × 10 ³ ) = 1.115 times the love A of Δ ⁻ (1232).

It is summarized in the table.
Love of Δ ⁻ (1232), Love of Σ ⁻ and Love of Ξ ⁻ and Love of Ω ⁻

What you can understand from this table
1． In the ^{sun, Δ - (1232), Σ} -, Ξ -, Ω - was possible.
2． The can was field ^{A, Δ - (1232),} Σ -, Ξ -, Ω - mass energy are different.
3． The thing that can be made in a high-energy field becomes high-energy electromagnetic, and becomes a high-energy particle. The orbit becomes smaller. ^{Δ - (1232), Σ -} , Ξ -, Ω - the "unity of mass and electromagnetic mass particles" How in either.
"Unification of particle mass and electromagnetic mass"
Particle = electromagnetism of one bundle of electromagnetic waves = 7.028 × 10 ¹⁷ electromagnetism = particles of one electromagnetic bundle = mass of Love particles = E ÷ c ^{2 The} mass of the particles (particles of one electromagnetic bundle) is obtained.
The mass of the particles (particles of one electromagnetic bundle) is obtained by the following equation: mass of particles = 9.628 × 10 ⁻⁴¹ Jm ÷ orbital.
The mass of the particles (one electromagnetic bundle) is obtained by the following equation: mass of particles = 1.111 × 10 ⁻¹⁷ × particle energy.
The mass of one electromagnetic particle is obtained by the following equation: mass of one electromagnetic particle = mass of particle (mass of electromagnetic particle) ÷ electromagnetic number of one bundle.
The mass of one electromagnetic particle is obtained by the following equation: mass of one electromagnetic particle = 1.370 × 10 ⁻⁵⁸ Jm ÷ orbital.
Find the value of the energy of one electromagnetic particle ÷ the mass of one electromagnetic particle.

· Delta ^- Rab particles (1232) mass ^{= 1.950 × 10 -10 J ÷ (} 9 × 10 16) = 2.167 × 10 -27 Kg
Particle mass = 9.628 × 10 ^-41 Jm ÷ (4.444 × 10 ^-14 m) = 2.167 × 10 ^-27 Kg
Particle mass = 1.111 x 10 ^-17 x 1.950 x 10 ^-10 J = 2.166 x 10 ^-27 Kg
Mass of one electromagnetic particle = 2.167 × 10 ⁻²⁷ Kg ÷ (7.027 × 10 ¹⁷ particles) = 3.084 × 10 ⁻⁴⁵ Kg
Mass of one electromagnetic particle = 1.370 × 10 ⁻⁵⁸ Jm ÷ (4.444 × 10 ^-14 m) = 3.082 × 10 ^-45 Kg
Energy of one electromagnetic particle ÷ Mass of one electromagnetic particle = 2.775 × 10 ⁻²⁸ J ÷ (3.084 × 10 ⁻⁴⁵ Kg) = 8.998 × 10 ¹⁶
Sigma ^- mass of Rab particles ^{= 1.694 × 10 -10 J ÷ (} 9 × 10 16) = 1.882 × 10 -27 Kg
Particle mass = 9.628 × 10 ^-41 Jm ÷ (5.115 × 10 ^-14 m) = 1.882 × 10 ^-27 Kg
Particle mass = 1.111 x 10 ^-17 x 1.694 x 10 ^-10 J = 1.882 x 10 ^-27 Kg
Mass of one electromagnetic particle = 1.882 × 10 ^-27 Kg ÷ (7.026 × 10 ¹⁷ particles) = 2.679 × 10 ^-45 Kg
Mass of one electromagnetic particle = 1.370 x 10 ^-58 Jm ÷ (5.115 x 10 ^-14 m) = 2.678 x 10 ^-45 Kg
Energy of one electromagnetic particle ÷ Mass of one electromagnetic particle = 2.411 × 10 ^-28 J ÷ (2.679 × 10 ^-45 Kg) = 9.000 × 10 ¹⁶
· .XI ^- Rab particle mass ^{= 1.761 × 10 -10 J ÷ (} 9 × 10 16) = 1.957 × 10 -27 Kg
Particle mass = 9.628 × 10 ⁻⁴¹ Jm ÷ (4.920 × 10 ^-14 m) = 1.957 × 10 ⁻²⁷ Kg
Particle mass = 1.111 × 10 ^-17 × 1.761 × 10 ^-10 J = 1.957 × 10 ^-27 Kg
Mass of one electromagnetic particle = 1.957 × 10 ^-27 Kg ÷ (7.027 × 10 ¹⁷ particles) = 2.785 × 10 ^-45 Kg
Mass of one electromagnetic particle = 1.370 x 10 ^-58 Jm ÷ (4.920 x 10 ^-14 m) = 2.785 x 10 ^-45 Kg
Energy of one electromagnetic particle ÷ Mass of one electromagnetic particle = 2.506 × 10 ⁻²⁸ J ÷ (2.785 × 10 ⁻⁴⁵ Kg) = 8.998 × 10 ¹⁶
· Omega ^- mass of Rab particles ^{= 2.175 × 10 -10 J ÷ (} 9 × 10 16) = 2.417 × 10 -27 Kg
Particle mass = 9.628 × 10 ⁻⁴¹ Jm ÷ (3.984 × 10 ^-14 m) = 2.417 × 10 ⁻²⁷ Kg
Particle mass = 1.111 × 10 ^-17 × 2.175 × 10 ^-10 J = 2.416 × 10 ^-27 Kg
Mass of one electromagnetic particle = 2.417 x 10 ^-27 Kg ÷ (7.027 x 10 ¹⁷ ) = 3.440 x 10 ^-45 Kg
Mass of one electromagnetic particle = 1.370 × 10 ⁻⁵⁸ Jm ÷ (3.984 × 10 ^-14 m) = 3.439 × 10 ⁻⁴⁵ Kg
Energy of one electromagnetic particle ÷ Mass of one electromagnetic particle = 3.095 × 10 ⁻²⁸ J ÷ (3.440 × 10 ⁻⁴⁵ Kg) = 8.997 × 10 ¹⁶

This is shown in the table.
The mass energy of the lab, the orbit of the lab, the electromagnetic number of the lab, the energy of one photon generated by the lab in one revolution and the mass of the particle = E ÷ c ² and the mass of the particle = 9.628 × 10 ^-41 Jm Orbit, particle mass = 1.111 × 10 ⁻¹⁷ × particle energy, one electromagnetic particle mass = particle mass ÷ electromagnetic number, and one electromagnetic particle mass = 1.370 × 10 ⁻⁵⁸ Jm ÷ orbital And the energy of one electromagnetic particle ÷ the mass of one electromagnetic particle
Table 28

Things that can be understood by this
1． The mass of the lab is 1.8 ~ 2.4 × 10 ⁻²⁷ Kg.
2． The mass of one lab electromagnetic is 2.6 ~ 3.4 × 10 ⁻⁴⁵ Kg.
3． "Delta ^- (1232) Love and sigma ^- Love and .XI ^- Love and Omega ^- Rab and mass of the particle delta ^- (1232) Love and sigma ^- Love and .XI ^- Love and Omega ^- Rab The "unification of electromagnetic mass" is established. What is the mass energy of a quark rotating in the lab?
Understand what percentage of quark's mass energy is that of love.
Delta ^- (1232) Love and Σ of ^- Rab and .XI ^- Love and Ω of ^- rotating through the Love, to calculate the mass energy × 100, the value of the mass energy ÷ Rab quark.

It is summarized in the table.
Delta ^- (1232) Love and sigma ^- Love and .XI ^- Love and Omega ^- table 29 or the mass energy of quark which rotates in the Love is a percentage of the mass energy of Love


What you can understand from this table
1. The mass energy of a quark rotating in the smallest orbit is 0.47% to 12.3% of the mass energy of the lab.
The mass energy of the quark rotating in the second smallest orbit is 0.40% to 7.74% of the mass energy of the lab.
The mass energy of the quark rotating in the third smallest orbit is 0.33% to 5.89% of the mass energy of the lab. Delta ^- (1232) Love and sigma ^- Love and .XI ^- Love and Omega ^- Is orbit of quark which rotates in the Love is what is.
The table shows the orbit of the quarks rotating in the lab.

It is summarized in the table.
Track of a quark rotating in the lab 30

This is illustrated.