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So let's say we have a quark there, a pair of quarks, they fall into a black hole. And the more they're pulled apart, the stronger they'd hear to understand a quark. And you try to pull it apart, well, if you turn it off energy, you'll end up with a quark, any quark up here. And so you can do it. And I mentioned earlier, it's on both virtual particles. You have a particle, an anti-particle pair, and they annihilate almost instantaneously. So you might be thinking, well, if you have a quark, and it falls into a black hole, it becomes a pair. You have your four-handed quark pair. What isn't it? Why don't they come into contact and annihilate? Well, actually, strong force comes into effect. You have strong force that holds everything together within the nucleus of an atom. And the particle that's the force barrier for that is a gluon. So the gluon is a mediating force that prevents the quarks from annihilating. And when you form a quark, an anti-quark pair, the gluon comes into the rescue and stops them from destroying each other. But a quark pair falls in a black hole. So as I mentioned, the more they're trying to pull them apart, the stronger they just adhere to one another. It's like a rubber band. If you take a rubber band and stretch it out, you'll find that as you stretch it further and further, it's acquiring more energy to keep pulling it. So at some point, they will separate. The quark will separate with the same energy it took to pull them apart, and that could be immense. And that energy will result in two more quark pairs, then four, et cetera, et cetera. And the process goes on and on and on. So inside a black hole, the theory is that the process of quark pairs being created as they enter the singularity will terminate at some point, where the energy produced in front of here would become so great it would destroy the gravitational field of a black hole. So once the gravitational field of a black hole is completely gone, well, that's the main characteristic of a black hole. It's dropping. So this is all theory. No one really knows what goes on inside a black hole. And they really don't. It's all just theory. Well, in fact, the singularity, they don't even know if there's actually a singularity there. Singularity is where all terms of mathematics and physics breaks down. So it's not a way of saying, you know, don't know what's going on there. It's dropping. In fact, the singularity at the point, there's a phrase that's used with that. And it's a god divides by a zero here. So that was attributed to Einstein. There wasn't an Einstein come up there. It was actually a comedian, Steven Lightman, came up with that phrase. I'm not sure what context he was using. But it's applied here with the singularity. And so this is a way to express how math becomes undefinable at a black hole center, which is actually the term for singularity, where mathematics and physics break down. So probably the thermal process of continual quark pair production could result in a quark-gluon plasma. So as I mentioned, you have the gluons come into effect there. So it allows the production of these quarks so that they're not destroying each other as they come into existence in quark and big quark pair. And I hope we'll get to much more about them in the particle physics here about things. But what I'd like to find interesting too is quarks. They come in flavors and colors. And it's not flavors that you would be accustomed to take a sip of your favorite pop or coffee that has a flavor. You look at a scenery outside, you see the greens. And the crescent milk is checking the factors. These are just basically just metaphorical expressions to help describe some characteristics of quarks that's dropping. Flavors, up, down, sharp, strange, top, bottom. The flavors describe the mass and the electric charge on the quark. Goes from low mass up to high mass. Will be up down quark to the lowest of the masses right to the top model, which is the higher masses. And it's going left or right. Press a proton. It has a 2-3 charge quarks in 1-3 charge now quark, which gives a net positive charge. And there are all kinds of quarks. And any quark pairs are being created all the time. In fact, in a proton, these are the valence quarks. And one I just mentioned are valence quarks. They're the main quarks. But there's all kinds of different quarks in a proton that are being created all the time. Quark, anti-quark pairs are coming into existence and popping under because at that time. So they're there all the time. And then there's color. As I mentioned, color. This has a great interaction of the strong quarks. So it's actually a color charge. Red, green, blue. November, Quebec, November. All star, node 6222. So you need three quarks. You need three quarks to make any particles. So the proton in the project, three quarks to make up any of those particles. And each one comes in a flavor. And that corresponds to the color. So it's important that regardless of the flavor, the colors, which are primary colors, red, green, and blue, all combine to produce light. So if you're adding quarks to make something up, you could take an up quark and maybe another down quark and maybe another up quark. But you have to make sure they all have red, green, or blue. So the final product would be white. So it's giving balance to the strong force when they're being held together in the atom. So pulling quarks apart, it produces quarks, anti-quark pairs. And as I mentioned earlier, annihilation. It's just mitigated by the strong force carrier or blue ones. And quarks and anti-quarks, they differ only under charges. So anti-quarks are shown with a bar over the sample. So an up quark would have a bar over it. A down quark would be a B with a bar over it, et cetera. And another line, probably, concept too, is there could be atomic hadrons out there. Hadrons, the composite particles, could have more than three of these valence quarks in their makeup. So they could have four, five, six, seven, or more. These are just theoretical, of course. But the up and down quarks are the most stable and the most common in the cosmos. So strange charm, top, bottom, or the production of higher energy equations, both natural and artificial, artificial and magnetic, in part of what's called reson colliders.