The Muon g-2 anomaly is solved, and researchers have saved the Standard Model. That is one thing that we should be glad about. Except the fifth force is not found. But before we try to hunt the fifth force, we must describe it. It's very hard to make the description about the ghost, a force that might not be anything that we have seen before. Or maybe, the fifth force is only a mirage, or a virtual effect some kind of reflection of some other forces.
We know that all four fundamental interactions or fundamental forces, strong nuclear interaction, weak nuclear interaction, electromagnetism, and gravitation or gravity are wave movements that the particle called boson sends. Every fundamental interaction has its boson, that carries that force or interaction. And the transmitter, or carrier boson’s size determines the wavelength of each individual force.
Strong nuclear interaction has the shortest of those wavelengths. That wavelength depends on the size of the boson that carries that force. Gravity is the only fundamental force that can interact over long distances. Gravity is also the only fundamental interaction that has no repelling effect. The quantum gravity model explains things like this: all particles that have mass are the gravity centers, which we can call a gravitational quantum dot.
And all gravitational centers from atoms to planets and black holes involve a certain number of those gravity quantum dots in a certain volume. So the density, or distance between those gravitational quantum dots determines the power of gravity. But then we can say that all fundamental forces or every boson can send radiation at a long distance, but we cannot see that radiation.
When gluon, the boson that transports the strong nuclear interaction sends radiation in wavelengths that we call a strong nuclear interaction that radiation or wave movement doesn't disappear when it travels out from the atom's nucleus. Other fundamental forces just cover that radiation into them. The reason why we cannot detect that strong interaction over long distances is simple. The strong interaction oscillates so small a point in the atom, that we cannot separate it from the whole.
Other interactions like weak nuclear force and electromagnetism, or their transmitter particles send radiation that affects larger parts of the atoms. And that's why we cannot see strong interaction. The model with gluons is that it's quite similar maybe, quite flat, to a photon. That flat particle creates the quantum channel or quantum tornado between quarks. Gluon transports energy out from the quantum channel to the point where it is. So the gluon acts like a thermal pump that pulls quarks close to each other.
When gluon transports or conducts energy out from the bond that keeps quarks and hadrons it must get that energy from somewhere. That somewhere is the hadron's quantum field. This is the thing called evaporation or vaporization. When gluon sends energy out from the quantum channel it turns particles into radiation, or wave movement.
When a particle evaporates it loses its mass. And when its quantum field turns weaker the outside quantum field tries to fill that point. The effect is similar to the case in which we bring ice to the room. When ice melts it conducts energy in it. In the same way, all evaporation requires energy. If we think that material is ice, we can ask why things like nuclear fission, fusion, or some annihilation release so much energy.
Maybe we should rather ask: what puts energy travel in that case moving so fast that it causes a strong effect? When we think about things like annihilation that happens between the particles. And their antiparticle pairs. Antiparticles are similar to particles, except their polarity or spin is opposite to their particle pair. When those particle-antiparticle pairs come too close to each other. Electromagnetic force pulls them together.
In that process, those particles will go in the same quantum field. Then those particles hit each other. In that case, they turn flat. The impact pushes their internal quantum fields away. And then the quantum fields impact that point. The impacting quantum field forms the slam. That destroys those particle's structure. The reason for that is the resonance between superstrings, the smallest structures in the particles. That rips those particles into pieces. When those strings that form elementary particles rip quantum fields travel to that point.
Same way when heavy elements like uranium or plutonium divide the quantum field falls between half of those particles. When heavy elements divide. Quantum field travels inside that thing. That field rotates protons and neutrons. And those things release energy from the nucleus.
In fusion, impacting energy causes an energy wave.
The reaction goes like this: Deuterium (2H) + Tritium (3H) → Helium-4 (4He) + Neutron (n). That thing means that the released neutron is the thing. That makes the energy released in fusion. The thing that makes the lightweight atoms make more effective fusion is this. In heavy atoms there is too much free space that their fusion can release more energy than the reaction uses.
The idea is similar to the case where we throw softballs against each other. There is so much free space in those balls, that they cannot form noise. When small, or light atoms hit together. There is less free space. Protons and neutrons cannot slip in that free space.
When we think about particles like mesons that have more than three quarks. Or they can involve two quarks. The meson is also a baryon, but it's the bosonic hadron. Simple structure mesons are more common than complicated mesons.
Baryonic hadrons like protons and neutrons involve three quarks. If there are only two quarks in the particle's quantum field it pushes those particles away from each other. If the energy level between quarks rises too high that energy pushes quarks away from each other.
https://bigthink.com/starts-with-a-bang/anomaly-muon-g-2-puzzle/
https://en.wikipedia.org/wiki/Fundamental_interaction
https://en.wikipedia.org/wiki/Meson
https://en.wikipedia.org/wiki/Standard_Model
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