If something is working, it didn’t happen accidentally.
Randomness can’t even build a bobsled. Ditto for natural selection.
Quarks are many subatomic particles carrying a
fractional electric charge that are building blocks of the hadrons. 2. Quarks have not been directly observed but predicted based on their existence and have been confirmed experimentally.
A quark is a fast-moving point of energy. Quarks are the constituents of composite particles labeled as hadrons. The proton and neutron are prime examples. Protons and neutrons are made up of three quarks. Protons and neutrons are composed of two types of quarks: up quarks and down quarks. There are several varieties of quarks. Two quarks make up a meson. A baryon composed of three up quarks is known as the delta particle. There are many quarks and gluons in each proton, but they average out to three quarks overall. Different quark flavors exist, and when you put them together in threes with additional possible angular momentum and radial excitations, you get the observed hadron states. Hadron states that three identical flavors have spatially symmetric wave functions. There are always three quarks per baryon.
If something is working, it didn’t happen accidentally.
Randomness can’t even build a bobsled. Ditto for natural selection.
Quarks are elementary particles, but they have no meaningful measure of size. Depending on the local gauge symmetry always operates on three quarks. Antisymmetric combinations of the three fundamental representation colors are meson states. A quark-antiquark combination would have no color, but so could a triplet of red, green, and blue; those three colors are used together on a TV screen to generate white. There are baryonic resonances that contain three up quarks and three down quarks. These particles are unstable to strong interactions and decay in less than a flash. In the Standard Model of particle physics, many interactions involve three particles. Quarks are held together by interacting with the gluon field. The quarks interact with a force field, the quanta of which are called gluons. The gluon field is very similar to the electromagnetic field with the critical difference that, unlike the photons of electromagnetism, the gluons carry a color charge and interact with each other and other quarks.
In the build-out for the fundamental layer of reality. All things are triune with binary interactives. Both mass and reality are built in this triune/binary manner.
Quarks are held together by the strong force. It acts between subatomic particles of matter. The strong force binds quarks together in clusters to make subatomic particles, such as, protons and neutrons. Gluons are responsible for binding neutrons and protons together inside the nucleus of an atom. This is crucial for building atoms, but this nuclear binding is actually a side effect of what the gluon really does. The gluons primary job is to hold together the quarks that make up protons and neutrons.
Quarks are colored objects and color electric fields are confined to a scale smaller than the scale of individual nucleons. Nucleons interact via exchange of colorless mesons, which are bound quarks and antiquarks.This force is the residual strong force. It is separate from the force that acts directly between quarks confined within the same nucleon. The force that binds nucleons and pions are actually bound states of quarks and gluons.
The existence of free quarks or gluons in the vacuum of space, can’t happen. Concurrently, nucleons can exist as free states at large enough distances.
If something is working, it didn’t happen accidentally.
Randomness can’t even build a bobsled. Ditto for natural selection.