Quarks, gluons, and symmetry.

"A recent experiment led by Mississippi State physicist Dipangkar Dutta has shaken one of physics’ most reliable concepts: symmetry. Credit: Shutterstock" (ScitechDaily, Rethinking the Universe: New Findings Rewrite Rules of Subatomic Matter)

The new research breaks the rules of physics. When an electron collides with quarks, it will not always decay and reassemble symmetrically. That means there is a problem with symmetry in the quarks. The Pauli exclusion principle, which states that no two identical fermions can occupy the same quantum state in the same system, explains many aspects of the existence of atoms and subatomic particles.

Because those particle's energy levels are different. That difference causes energy flow. That keeps them in their entirety. 

If there are two identical fermions. That causes the quantum flash that pushes those particles away. When quarks decay they can reassemble themselves. That requires that both of those parts are in the same quantum field. 

That quantum field is like the bag that denies the quantum shadow, or quantum bridge fill. That quantum shadow pulls those quark's halves back together. But there seems to be a situation where when an electron hits quakes the quantum field fills that bridge. If a quantum field turns between parts of a decayed quark, that field denies their reassembly. 

There is also the possibility that if those decayed parts of the quarks spin oppositely that event turns the quantum field between those particles into a shape that looks like twisted fabric. That means the energy density or energy level between those particles rises so high, that they cannot cross that bridge. That is one of the most interesting things in modern physics. That helps researchers make models about the strong interaction. 

Because energy travels from quarks to gluons. Gluon aims for energy flow to the outside. Because energy travels from quark to gluon, that acts like a thermal pump. It keeps those quarks close to each other. The reason why gluons can bind quarks together is that it cannot get energy from emptiness. It collects that energy from the system where it exists. 

The idea is that quarks spin. The spinning quarks also bind energy into them. The problem is that those quarks sometimes release that energy. That happens when their energy level turns higher than their environment. The gluon is like a thermal pump that aims for energy that the quarks release. 

That means the gluon that is in the quantum shadow between quarks keeps the energy flowing in a certain direction and a certain way. Without gluons, the quarks release their energy symmetrically, and that energy flash pushes those quarks away from each other. The gluon's role in the system is to keep energy flow stable. Because it binds energy from the quark's quantum fields it pulls them into it. That thing causes a situation in which the outside energy starts to push those quarks into the form that we call hadrons. So energy flow between quarks keeps that structure in its form. 

The idea is that the gluon is an extremely fast-spinning particle. That is a little bit flat. That particle binds quantum fields from quarks into the kinetic energy. When quarks come close to each other there forms a quantum (or energy) shadow between them. When gluon spins in that energy shadow it binds energy. 

And deepens that quantum low pressure. This thing stretches those quark's energy fields. Then the fast-spinning gluon binds those fields into themselves. Then the gluon acts like a centrifugal plate that aims energy to the sides of it. Because gluon conducts energy out from the system it pulls those quarks together. Or, otherwise, we can say that outcoming energy pushes quarks near each other. 

If we use a superstring model with gluon that thing looks like the plate that is formed of the strings or wires. Or, otherwise, it looks like a flat whisk. Those wires, or superstrings throw quantum fields to the sides of that particle. The gluon allows the quantum spikes that the quarks stretch quantum field forms to touch the gluon. The gluon aims energy out from them. And that forms quantum low-pressure. 

The strong interaction is the thing that keeps protons and neutrons in their form. In those hadrons, the outcoming energy or quantum fields push quarks so that they can keep their formation in hadrons. That means there is so-called quantum low-pressure that keeps quarks in the forms of protons and neutrons. 

There are models where the gluon. The strong interaction transmitting particle spins between those quarks. That means gluon binds energy into itself. When gluon touches the quantum field around it binds that field into the kinetic energy. That energy pulls the quarks together. When gluon goes between quarks. It pulls energy from the quark's quantum fields. That thing makes those fields stretch. And the gluon simply conducts energy out from that point. 

https://scitechdaily.com/rethinking-the-universe-new-findings-rewrite-rules-of-subatomic-matter/

https://en.wikipedia.org/wiki/Gluon

https://en.wikipedia.org/wiki/Hadron

https://en.wikipedia.org/wiki/Quark

https://en.wikipedia.org/wiki/Standard_Model