The shape and basic structure of proton neutron _ the final answer

Lithuanian monks (Wu Xiaohong, Baiyun Clinic, pengshan county, Sichuan)

Introduction: The structure of elementary particles is completely unified for the first time!

Uncover the intuitive form of proton neutron for the first time!

Uncover the specific structure of proton neutron for the first time!

For the first time, comprehensively decipher the mystery of various particle decay!

Key words: ring * centrifugal force * three meson overlap * double-layer structure * Coulomb constraint * nuclear gear.

I mentioned in my last paper that mesons and baryons are composed of positive and negative electrons. The positive and negative electrons are paired, end to end and move in a circle, finally forming a closed ring. About 120 pairs of electrons form a neutral y meson with a rest mass of 135- 140 (tentative name, equivalent to the derivative meson mentioned in the past, because this letter can't be typed here). Due to this circular motion, the electron pairs form a hollow structure. Three neutral y mesons of equal size overlap neatly to form a neutral one.

1 (I): positron * negative electron * positron-

2 (middle): negative electron * positron * negative electron-

3 (below); Positron * negative electron * positron-

These three neutral Y mesons with the same size overlap up and down, forming a closed ring and rotating together. _-_-This is the k0 meson. But it is also unstable. At the same time, the periphery of the K0 meson (note: it is the periphery! Or the outer layer! Then, three neutral q mesons (tentative name. Because these three Q mesons are formed after the inner K meson, it is difficult to find them in the laboratory, but they will appear in the later proton collisions.) The rest mass is about 170- 180, and a neutron with a rest mass of about 930-940 is formed.

In other words, neutrons are composed of six elementary mesons, all of which are round in shape. * * * is divided into two layers, and the inner layer consists of three neutral Y mesons of equal size. The outer layer is composed of three other neutral Q mesons with the same size (the radius of the outer layer is slightly larger, and its electrons are more than that of the inner layer), and the three overlapping neutral Y mesons in the inner layer form a neutral K meson, whose rest mass is between 405 and 420. (In Atomic Physics edited by Jun Lin Sheng, the rest mass of the K meson is between 490 and 500, which is easy to understand: the extra part is due to its outer layer when it is formed. That is to say, when you intercept a k meson in the laboratory, it is actually connected by pairs of electronic strings. The K meson is unstable until its external structure completely forms three overlapping Q mesons, but the first step of K meson decay is to separate three overlapping Y mesons and simultaneously separate the positive and negative electron strings with 80-90 rest mass. Only this pair of electron strings attached to three ring mesons were not observed when they disintegrated). The outer three neutral Q mesons are called a neutral "super-K" meson after overlapping and combining, and its rest mass is between 5 10-530 (as shown below).

Neutron ***6 meson: three Y mesons in the inner layer form a K0 meson; The three Q mesons in the outer layer form a super-K meson.

With the inner and outer layers, neutrons are relatively stable. At this point, all the positive and negative electrons in the six elementary mesons are paired. However, due to the centrifugal force generated by extremely fast rotation, this relatively stable neutron finally emits a negative electron on the peripheral super-K0 meson to form an orbit _ _ _ _ _ _ and the neutron deteriorates (the peripheral super-K0 becomes super-K+).

Proton: inner layer 1 K0 meson; Outer layer 1 super K+ meson

Why are positrons emitted instead of positrons? Because of the mass relationship: the rest mass of positrons is slightly larger than that of negative electrons. Only when there is an abnormal situation _ _ _ _ when the mass of a positron is less than the mass of a negative electron _ _ _ _ _, can a positron be launched into orbit to form an antiproton!

The question is why only one negative electron flies out of the periphery? There are three q mesons on the periphery. From which Q meson did this electron fly out? The biggest possibility is a Q meson in the middle, because which meson in the middle has the largest centrifugal force! When a negative electron enters the orbit, the neutron degenerates and a single positron appears on the middle surface of the proton, as shown in the figure;

1 positron * positron * positron * positron * positron * positron-

2 negative electron * positron *-negative electron * positron.

3 Positron * negative electron * positron * negative electron * positron * negative electron-.

Because there is a negative electron missing from the meson in the middle of the proton outer layer, there is an extra positron, and this extra positron has Coulomb binding force on other originally unstable negative electrons. As long as all the negative electrons in the proton are constrained, the positron will be more stable, so the proton enters a stable state.

When a neutron is combined with a proton, there are six annular mesons in the inner and outer layers. The binding force of a single positron on the proton on the surrounding negative electrons (including neutrons), coupled with the weakening of the rotation speed after the proton is combined with the neutron, makes the centrifugal force relatively smaller. When neutrons combine with protons, they also become stable-that's why neutrons combine stably in the nucleus. In the above picture, the ring formed by meson 2 in the outer layer of proton is not completely closed, but is connected with the inner layer and Q meson 1 and No.3 on both sides of the outer layer, so meson 2 is also stable-only when the nucleus is hit by a strong train. ! Common artificial radiation elements with 2 or 3 cycles! However, the decay is slow and takes several to ten minutes to complete (please refer to the article "Unlocking the Secret of Core-Shell Structure of Nucleus" for details).

Why do neutrinos appear after neutron decay? Now some scholars think that neutrons are composed of electrons and neutrinos, but this is actually an illusion: that's because electrons are composed of neutrinos and photons, neutrinos are very thin (and photons are hard, so only two photons are found when a pair of positive and negative electrons collide), and the outer layer of neutrons emits a negative electron. When its negative electron breaks free from positrons, the neutrinos in its contact part are partially separated.

Now let's analyze baryons other than proton neutrons. It is actually very simple to produce these baryons: they are all 1 to 4 Y mesons or some positive and negative electron strings temporarily combined on both sides of protons A and B, _ _ _ _ _ _ but these attached particles are just passers-by!

To sum up, proton is the most stable hadron, which consists of an inner K0 meson and an outer super K+ meson. This stable structure can only decay when it collides: when a Y meson (with a negative charge of one unit) collides with the proton, the Y meson temporarily forms a hyperon with the proton, and at the same time, the Y meson knocks the K0 meson out of the proton from the inner layer-this phenomenon is called.

The shape of electrons can certainly be spherical or nearly spherical, so proton neutrons look like a hollow tire. Because electrons are spheres, the upper and lower surfaces and the inner and outer surfaces of the proton ring form a uniform gear. This gear will go back to my article "Unlocking the Secret of Core-Shell Structure" to re-understand, and you will be extremely surprised to find that the structure and movement of the A-plane and B-plane (here, the upper and lower sides) and the whole surface of the nucleus are the same as those of our current mechanical gear. ! We can completely understand the collective motion of each nuclear column in the nucleus as the most perfect mechanical motion! !

Finally, let's verify the accuracy of my proton neutron structure-according to the data in Atomic Physics edited by Jun Lin Sheng, among all Y mesons that hit protons with unit negative charges or with protons, only one hyperon or K0 or K+ meson is produced, but the K meson with unit negative charges has never been observed! Now we can easily explain it by the structure of protons: because there are only K0 and K+ in protons, there is no K meson with unit negative charge. Load again; When the neutron hits the neutron, why don't neutral hyperons and neutral k mesons appear? My understanding is that the negative electrons in the neutron outer layer are inherently unstable. Once they hit, the negative electrons will fly out of the ring! ! (When a proton encounters an impact, although a single positron will fall off, it will take a long time, as I said just now. )

Conclusion:

When this article and the article "Opening the Core-Shell Structure of Nuclei" published ten days ago were finished, I firmly believed that I had found the real world of those elementary particles and the internal structure of the nucleus. When the real world appears before our eyes, everyone will be surprised _ _ _ _, because it is far from our initial judgment! But now it's so real and reasonable. Maybe it's our experience that made us touch the elephant for nearly a hundred years. Those advanced mathematical operations don't really show us the intuitive form of the nucleus. Repeated experiments and analysis have not finally found the particle structure model. Fortunately, because of the existence of these experimental data, we have a point-to-point thinking and a basic direction close to the truth! Now, when we discover these secrets, in turn, we revise some of our experiments and even misjudge them!

I have every reason to believe that these two papers are an epoch-making leap in atomic physics! It has solved many problems in the past hundred years and found a broad road in the microscopic physical world where mountains and rivers are in doubt and there is no way out. It may be ignored or even rejected by traditional authorities in a short time, but no one can finally stop the progress of science! !