You’re welcome!

In the same way that atoms are bound states between electrons and protons having an equal amount of positive and negative charge to have a net neutral charge, quarks are bound within nucleons by having a combination of color charges that result in a net neutral charge. However, there is always an imbalance; as a quark emits a gluon to change its color charge in order to balance out with the other quarks, color charge is conserved with that gluon, which alters the color charge of the quark that absorbs it, knocking the quarks back out of balance and forcing another quark to emit another gluon to change its color charge, which repeats the cycle. Here’s a helpful visual: https://commons.m.wikimedia.org/wiki/File:Quarks.gif

It’s also helpful to mention I was inaccurate in my initial comment; there are six color charges, not three. RGB and anti-RGB. Quarks only have RGB charges, whereas gluons are any of 9 combinations of color-anticolor charges. So a quark emits a gluon to change its color charge, the gluon has a color-anticolor charge to conserve color charge, and then must change the color of another quark when it is absorbed as the anticolor charge of the gluon and color charge of the quark cancel out, leaving the initial color charge the emitting quark gave off.

It can be thought of as potential energy being converted into the virtual particles. Since the negative charge of electrons repel each other more powerfully the closer they get together, at a certain distance it becomes more energetically favorable for virtual particles to be spontaneously emitted than it is for the electrons to exist that closely together. They can exchange the particles indefinitely, but the energy still comes from an outside force shoving them into one another, otherwise they would just redirect and never collide again.

They’re suspected to be excitations in the underlying quantum field corresponding to that particle. I.e. There are no electrons, just excitations in the electron field. Are the ripples on the surface of a pond physical structures distinct from the pond itself?

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Thanks, it’s the autism.

Edit: To be more clear, I just meant the grass is always greener. Some people can intuitively grasp scientific principles, some people can intuitively carry a conversation. One is flashy, one is necessary for mental health.

I do my best! I spend all my time obsessively reading up on such topics because, frankly, I couldn’t imagine anything more important than understanding how the world around us works. I do have a few other hobbies, but all roads circle back to quantum mechanics. And understandably, nobody else really wants to talk about it because it doesn’t interest them and they find it complicated (which I suspect is only because they find it boring; people say I’m “so smart” but I think most of the credit lies with me happening to find the topic truly fascinating) so I spend a lot of time trying to think of accessible explanations in the off chance someone is willing to listen to me ramble.

I think our understanding is mostly just observational at this point. Color charge “must” be conserved because we’ve never observed any phenomenon in which it wasn’t. It’s like the conservation of mass and energy, except it’s really the conservation of symmetry. High energy collisions of photons can create matter, but it’s always in matter-antimatter pairs. Anti-particles carry equal but opposite charges of their particle counterparts in order to maintain symmetry. We can’t just create charges out of nowhere. For example, neutrons (net neutral) can decay into protons (net positive) by emitting an electron which carries away the negative charge. So when quarks change their color charge, they must emit a gluon with a color-anticolor charge to carry it away.

We’re still working on the why, but all we know is that we haven’t observed anything that contradicts these observations. Or at least as far as I can recall off the top of my head; I vaguely recall something about weak interactions violating symmetry, but I don’t have that bit quite as well researched as the basics.