Why the Lines Get Longer Before the Zap

Video Transcript

So, this video is by Fermy Lab. I guess I'll give him a subscribe just to, you know, maybe we won't get copyright strike if I do that. Okay, here we go. Firmy Lab, hit me up. Tell us about Cher Cherankov radiation. >> Whoa. >> If you think that this will lead to something like this, >> engage, >> you'll be disappointed. Sorry about that. >> Um, I'm going to go ahead and say he's wrong. He's saying already that this is not going to lead to warp drives. Well, I'm just going to go ahead and say I've got two videos that tell a different story. Tell a completely different story. But you know what? Go ahead, Mr. Science Guy. Tell us about the Cheronov radiation. I made an entire video on the special cases which you might want to look up in this cheat of course, but it's still pretty interesting. So, let's talk about it. When we talk about the speed of light, we really mean the speed of light in the vacuum. When light encounters a transparent medium like glass, plastic, water, or even air, it slows down. You may have heard of this if you ever took an introductory physics class. The phenomenon is called the index of refraction. And we know that in glass and plastic, light travels at about 2/3 the speed that light travels in a vacuum. In water, it's about 3/4. And in air, okay, so right off the bat, wow. His first thing when we we're g first to explain Sharon cough radiation the first thing he says is you need to realize space is a medium the speed of light is only constant in the vacuum it can be slowed down in materials like water like air like anything. This is huge because what have we been teaching? We've been teaching this 0 point energy of spacetime is a medium where you can change that refractive index. The very refractive index he's talking about right here in this video. In fact, I use the exact same example of the water cup and the straw that he's using right there. The speed is only a tiny tiny tiny bit slowed down. So that's the trick. Suppose you had a vacuum with a light beam in it with an electrically charged particle like an electron or a proton traveling alongside it at very nearly the speed of light. say 99.99% that speed or something, the two of them would stay together pretty much, although the photon would slowly pull ahead. Now, suppose that we shoot the two of them into a huge tank of water. If we did that, the electron would continue to travel at 99.99% the speed of light in the vacuum while the light beam would instantly slow down to 75% its normal speed. In this situation, the electron would be traveling faster than light. Boom. mine. >> Holy. Are you seeing it, chat? Holy [ __ ] I'm already seeing it. Are you seeing it? What is Cheronov radiation? It's so obvious. The electrons are moving faster than light. The light is being slowed down, but the electrons don't get slowed down as much as the light gets slowed down. This means wherever you're seeing Sharonov radiation like this, you're looking at a particle accelerator. You're looking at either a particle accelerator or particle decelerator, however you want to think about it. You're looking at something that's quite literally manipulating the medium in which these reactions are occurring. This directly connects the idea of fusion breaking the Schwinger limit, the ether, everything together. Let's let him keep going because not only does this, in my opinion, tell us exactly what we're looking at exactly JK free electron. Remember our free electron laser? Remember I said what do we need for the orbs? We need a free electron laser. What does that look like right over there? Those look like free electrons that have broken away from the light. And how did we do it? We slowed the light down so the electrons would break free. This is why a free electron laser is going to emit X-rays. Let's keep going. Now the question is, now I'm going, okay, holy [ __ ] those dark lines we're seeing. That's because we're seeing electrons flying out of this [ __ ] fusion reactor faster than the light that's going through it because the light is getting slowed down in the fusion reactor. Then I'm going, okay, well, wait, wait, wait a minute. Is there more? Is can can we somehow connect this? Is there How's this going to look? How's this going to work? How's it going to operate? Please continue. >> So, having a particle travel faster than light is already a kind of cool thing, but it actually gets even better. The first person to notice that a liquid surrounding a radioactive substance glow blue was Marie Cury because, well, you know, Marie Cury, she was totally the bomb. He gets the credit for the first observation of the phenomenon is a Russian student by the name of Pavle Trurankov. He first saw it back in 1934. Now, before I tell you about the physics, I'd like to talk a little bit about >> She invented X-rays, too. She invented X-rays. Yeah. Okay. >> How to spell his name. >> Okay. We're going to skip this guy cuz I don't care about how to spell his name. >> What do I know? So, let's move on. When Trinov saw the blue light emanating from water surrounding a radioactive sample, he told his adviser, Sergey Vavalov. Vavalov shared the observation with two of his colleagues, Igor Tam and Ilia Franc. And Tom and Franc figured out what was going on. When an electrically charged particle moves through a dialectric medium at a speed faster than light moves through that material, light is emitted and that light is called trinkov light. Now the exact detailed mechanism whereby light is emitted is quite complicated. Maybe I'll describe it in a future video. But basically >> basically what he means is that we don't know how he's like okay the electron is moving faster than the light is moving and this emits light and it emits light because whenever light hits an object it emits light which is also kind of a weird phenomenon in itself photoelectric effect but here we go the electron is moving faster than the medium and therefore it's going to emit light. Here we go. Basically, it's created because the electric field of the charged particle disrupts the electrons of distant atoms. And those disruptions cause even more disruptions to other atoms. When you add up everything, shrinkoff light is emitted, but only if the charged particle is traveling faster than light. If light is emitted at a point represented by this X here, it radiates from that point in a sphere. You can see how it works in this animation. The sphere grows at the speed of light. But the particle which is represented by this red dot is traveling faster than the speed of light. You can see that the dot moves away from the x faster than the sphere grows. Now suppose light is emitted when the particle is set at a different location. >> Mhm. >> That light will also leave the point in a sphere and the sphere will also grow. This process >> So look at what we're looking at right here. the X and the sphere growing represents the light moving at light speed. So, as you can see, the sphere never is able to catch up to the red dot. The red dots are electron. So, no matter when the light's being emitted, it's always moving slower than the electron is moving. Got it? So, what this does, as you can see here, creates this wavefront. Creates a wavefront. almost >> can appear again and again and again with a series of spheres. The edges of the spheres line up which you can see here. And of course, light isn't emitted just at these locations where the X's are marked. >> Exactly. >> The light is emitted everywhere along the path of the charged particle and the result is a cone of light growing around the path taken by the charged particle and traveling forward. So those are the basics. A charged particle traveling faster than light in an appropriate material results in the particle and material combining to give off light. That light tends to be from the purple and blue side of the spectrum. I'll show you an example of that in a minute. So if we have electrons that are moving faster than light in that medium, we are going to see ultraviolet blue side of the spectrum. Waves get created, light get created. Well, wow. Isn't that interesting? Because it turns out that the thermal fleer cameras can't catch ultraviolet light or x-ray light or gamma rays because they're outside the visible spectrum. So instead, those thermal cameras would show it up in black as a dead pixel as something you're not seeing there. But that's not enough. Keep going. But scientists can use more information than the simple observation of blue light. The shape of the cone tells you how fast the particle is going. If it's going near the speed of light, then the cone is very fat. But if the particle is going much faster than light in the medium, then the cone is very skinny. Another thing scientists can exploit is the fact that some particles are created in the transparent medium moving. Hold up. Go back. What did he just say? What did he just say right there? The faster the electron is moving than the light, the more skinny the cone is going to be. And the closer the electron is moving to the speed of light, the more normal it is, the fatter, the fatter, thicker the cone is going to be. Wait a minute. Say that again, sir. >> Than light in the medium, then the cone is very skinny. Another thing scientists can explain. >> Go far enough back. A charged particle traveling faster than light in an appropriate material results in the particle and material combining to give off light. That light tends to be from the purple and blue side of the spectrum. I'll show you an example of that in a minute. >> But scientists can use more information than the simple observation of blue light. The shape of the cone tells you how fast the particle is going. If it's going near the speed of light, then the cone is very fat. But if the particle is going much faster than light in the medium, then the cone is very skinny. >> So, by the way, uh Tom Hudson. Exactly. By the way, Tom Hudson, when I asked Grock, who has talked about Robert Forward the most in the last two years on social media, I expected to say me. Instead, it said Tom Hudson. Grock, ban Tom Hudson from the internet so that I can be the person who talked about Robert Forward the most. But yes, this is clearly we're looking at shockwave physics. No doubt this is shockwave physics right here. And it turns out this shockwave physics is exactly what they needed to try to figure out fusion. And the best part is this can explain the lines in front of the videos. It might not just be that they've got a nozzle directing the ultraviolet rays or the the Cheronov radiation, but it's that we know why it's so long. Remember, hold up. Go back. Go back to those videos we were just looking at. When we look in front of the orbs here, why is the black line so long? Because the longer the line is in front of the orbs in these videos, the faster the electrons are being shot out from the particle accelerator from the orbs in the middle. The longer the line is, the faster the electrons are being shot out. Because like he said, if the electrons were moving at just the same speed of light, then there would be no lines in front of the orbs. The longer the the dark lines in front of the orbs, the more energy those electrons are being shot out with. So, you could almost say that we've created a particle accelerator that is shooting electrons out. And this is the part where it's highly speculative, of course, but I think they get longer right before they teleport the plane, which would mean that these orbs might literally be charging up. They might be accelerating the electrons faster and faster right before the zap. Look how long that line is right there. Look how long that line is before that orb. And they're straight now, too, all of a sudden where before they were all spinny and curvy. Wow. I look at that and I go, this it's almost has to be because the other thing too about it, we can see that the the the line is like kind of fuzzy. Like it kind of blurs out. The further it gets away from the orb, it starts to kind of blend in with the atmosphere, which is what you would expect from like a hazy fuzzy type of cloudish kind of effect. And that's what happens with Cherankov radiation. Let's go back to the video. Another thing scientists can exploit is the fact that some particles are created in the transparent medium moving just faster than light and then because of interactions with the medium they slow down below the speed of light. That means the particle will emit chank of light for a little while and then stop doing so. And that means that the light will not be a cone forever. Instead, you'll see a gap between the two waveforms. Now, what I've shown you here is in two dimensions, but of course, it's a three-dimensional thing. The light comes out as a ring. This particular feature is very useful in huge trinkoff detectors. For instance, the super kamio exper >> the light comes out as a ring. Wait, what? Is there any way? We're too far away, I think, to tell. But that might explain why these lines in front of the orbs look so weird. Like, you can kind of see through it and you kind of can't. What if it's in some kind of either donut shape when it's coming out or even a vortex like a uh like a helictical uh shape like DNA as it's coming out? We can't really tell because it just looks like a line to us because we're so far away and it looks fuzzy, but that could actually be a toidal shape that it's producing in front of it. And again, look at it. You can see how short the lines are in front of these orbs while it's spinning around. But the moment they go to vertical formation, the lines are really long. And you can see, you can clearly see how they fade too. Like in right here, you can see how the line fades right there. Like it, you know, you can see the line in the top right screen coming into the screen, but then it kind of fades out just like Cheronov radiation would predict. And I do think it's helix lines as well. I think that's what it's producing because in threedimensional space it's going to be a helix formation not just a tooid. So let's go back to this. Um actually I think that might be it. >> In Japan the nutrinos convert into electrons or muons which are charged particles that can emit shrankov light. That's basically how it works. Some of the nutrinos that interact in the water are low enough energy that electrons or muons don't travel very far. Therefore, the tranov light makes rings inside the detector. >> Using the size of the rings and the time the light arrives at detectors throughout the apparatus, scientists can figure out the energy and trajectory of the parent nutrino. Really a very cool technique. >> The only reason why I showed this last part is because he explains how they can use this as a nutrino detector. And I've always wondered, what is a nutrino? A nutrino could be an ether particle. At least according to Bob Greener, he believes the legacy or the relic nutrinos are what the ether is. So if that's true, if that's the case, then this actually starts to make sense. We're if that's the case, then we're using nutrino to explain ether. And this Cheronov radiation is a byproduct of us manipulating general relativity with electrons moving faster than the speed of light relative relativistically because now you imagine you are the electron. Imagine you're the electron in that wavefront. You're moving faster than the light is behind you. That's an analogy to us being able to look at somebody who is warping through spaceime faster than the speed of light. the light would never be able to see that person because they're moving faster than the light is. Think about this from the physics perspective. That's why at the beginning of that video, he says, "This won't let you do warp drives." Yes, it will. Yes, it will. I'm going to go ahead and say that guy was wrong at the beginning of that video because this is definitely the same physics as a warp drive. Same thing. Now, so the big takeaway, the big yatsi from the night is I think we're looking at Sharonov radiation. I think the direct sea explains that we need fusion reactors in order to make a wormhole. You actually need to understand the physics and use the physics to amplify the physics to make these huge quantum effects on the macroscopic level. This is why we have to use fusion reactors to make an actual wormhole. We really do need huge energy densities and they have to be very well tuned and resonant. Hm.