Video Transcript
inertial confinement fusion. Now, this is the form of fusion that they were doing with nuclear weapons. And what I think they figured out is a combination. They took the magneto inertial confinement of plasma and the plasma orbs and they combined it with inertial confinement fusion collapsing on all sides. Listen very carefully to what he says about inertial confinement fusion. Here I'm going to skip ahead just a little bit. >> That creates X-rays and then the pressure of those X-rays is supposed to make the target compress and and generate enough pressure that you can fuse the content. Okay? >> So you produce X-rays. So basically the light you shoot lasers light on your object causes X-rays to get produced and then the X-rays zap onto your object vaporizes the object fuses the object boom now you get your energy. That's the idea. The X-ray part is significant because we're literally looking at the X-rays in form of brelung radiation. I hope I'm saying that name right. I'll probably have to get Siri to tell me how you say it. >> Now, does this work? Um, not yet. And it's easy to understand what might go wrong here. Um, so here's a simulation. Uh, and you know, okay, so think think you have a balloon and now you have fingers trying to compress that balloon, right? And you know that if you compress here, the balloon will expand elsewhere, right? So what you try to do is to have many fingers compressing that balloon as uniformly as possible. Okay. And that's hard, right? To to achieve that degree of symmetry so that you result in uniform compression rather than, you know, compression here, expansion there. That's a very difficult thing to do. So, what you're seeing here is basically instabilities that are driven inside of this capsule by by by virtue of the fact that the irradiation by these lasers isn't actually unifor. >> Okay? Anybody trying to gaslight me and tell me we're not looking at inertial confinement fusion, just get out. Get out right now. We're definitely looking at inertial confinement fusion here. He even specifically calls out the fact that the compression needs to be exact from all angles, right? Because you can imagine a balloon. If you're compressing a balloon and it wasn't exactly equal compression on all sides, you're going to get these instabilities where it shoots out. But if you compress it equally on all sides, especially if you compress it vertically like that, vertically, where is it going to go? It's going to either go forward or it's going to go backward. Right? I'm compressing my object here. It's going to shoot out that way or it's going to shoot out that way. Those orbs are converging on that plane in a perfect equilateral triangle. Perfect compression. I can't even think of anything else that could be related to other than inertial confinement fusion. It has to be. It's the exact basis for inertial confinement fusion right there. So, this is where I go. When you think about this and think about the science, you go, "This isn't aliens. This is not aliens." Like, you can draw a direct map between when we figured this science out and how we were working on it. Magneto confinement fusion, inertial confinement fusion, and then we just took it to the next level. And now we're making nukes, but they're not really nukes anymore, are they? We're manipulating the atom, but we're doing it in a way that is a little bit more like Harry Potter at this point or Star Trek. So this is very much research in progress as is as is magnetic component fusion. Um and uh it it leads to all sorts of interesting physics that go beyond just looking at the actual fusion itself. And here's one of the interesting um aspects of these laser plasma interactions or laser targeting. >> This is really interesting in my opinion. So many times what happens is when you shine a laser at a solid target uh so in this case the solid target would be sort of in the at the bottom of this blob here of this green blob. So you shine the laser you ionize the target and you have an expanding cloud of material coming towards the laser. And then uh you have a temperature gradient because if you're closer to the laser you are hotter, right? And if you're further away you're colder. But you also have a density gradient because if you're closer to the surface, you are more dense. If you're further away, you're less dense. And as it happens, there's a battery mechanism that that is generated by virtue of the fact that the temperature and the density gradient are not aligned. They're sort of they can be perpendicular to each other. That's a battery that generates a magnetic field. And what you're seeing here is a simulation by um Kevin Sheffller who's a postto working with me um some years ago showing how when you set up that green blob as it were right a blob of density with a temperature gradient that's perpendicular to the density gradient you generate these magnetic fields like this >> I got to say chat this is one of the one this part here I didn't want to go too crazy on this but when he explains this to me yes it almost Sounds like a ZPE battery or some other type of monopole that's being created. He's saying that you can actually solve the temperature gradient that you're producing. Like you're shooting a laser at something. You're actually creating a temperature gradient. Remember the difference in temperature. And so now you're going to have these relativistic effects where you're going to have hot trying to flow to cold, but you're also going to have this pressure counteracting that. And so what's going to end up happening at the end? What if what ends up happening is that you end up pushing something directly through spaceime. What if you push it directly through spacetime? This effect, he says, basically produces magnetic fields. Produces magnetic fields just via this effect. Just via this uh fusion, this inertial confinement fusion effect. This is about as close as I think he gets here to broaching the idea of the ether. And then he actually follows this up with the next thing he says here >> that's called the beerman battery effect. And people do this uh routinely in laser plasma experiments. But it is also thought that this same mechanism the beerman battery is responsible for generating speed magnetic fields throughout the universe. Maybe because you have a supernova explosion that drives a shock front and at the shock front you can have density and temperature gradients that are misaligned and generate magnetic fields. >> This is crazy. He's basically saying here guys, if you're reading between the lines, he's saying that magnetic fields can arise from nothing. Magnetic fields can arise from the motion of matter throughout spaceime. that we can just magnetic fields can just spontaneously potentially uh appear and amplify. And to me, the question anybody should be wondering is where is that energy coming from? How how is that possible? From a classical view of an empty vacuum spaceime, tell me where those magnetic fields are coming from, where all that energy is coming from. If it's not primordial, then how does it exist in a natural system? >> The jump this the jumping slide where I go from talking about fusion to talking about magnetic fields in the universe. >> Skip a little bit ahead here. >> So here's a galaxy. This is M51. And this is supposed to be tracing the structure of the clusters themselves. That like the conventional wisdom these days is that magnetic fields themselves weren't really created at the big bang. Right? So there has to be some sort of plasma based mechanism by which you are going to create these magnetic fields essentially from nothing >> cat someone clip that there must be a plasmabased mechanism by which you're creating these magnetic fields essentially from nothing. Everybody talks about there's no free energy. Uh, well, my bro who just got assassinated says there's some free energy out there. Says that magnetic fields arise from plasma spontaneously. How about that? How about that? And the beerman battery that I just talked about is one possibility. You generate some sort of speed magnetic fields. And then you ask what happens to them as as the plasma sort of moves and evolves these magnetic fields. So let's talk a little bit about that. So all of these environments uh the earth's core the sun u solar system the interstellar medium galaxies g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g g galactic clusters, they're all plasmas. You can think of all of these all of these environments as plasmas. And so if you can think of them as plasmas, you might want to write down an equation for how a plasma evolves a magnetic field. And so I showed you I flashed this equation earlier. This is Ohm's law for a plasma. You might recognize it without this term. It just says electric field equals resistivity time current. You know when you were in kindergarten you saw voltage equals resistance time current, right? So this is sort of the differential version of that. This electric field equals resistivity time current. But of course the plasma is moving. So what you have to do is you have to write down the electric field in the frame moving with a plasma which is electric field in the laboratory frame plus U cross V. >> So right there there it was. When you ever hear the physicists say the magic word frame, the plasma's moving in the frame, whenever you hear them talk about the frame of reference, they're talking about general relativity. You live in your bubble. When I'm talking about you live in a bubble and you're experiencing things in your bubble and I'm experiencing things in my bubble and we're experiencing this shared reality between our bubbles converging, that's the frame of reference. My bubble is my frame of reference. Your bubble is your frame of reference. The plasma itself has its own frame of reference. Every particle in the plasma has its own frame of reference. That's where it starts to get weird when you start to calculate it because now you have to calculate, well, what does this one particle see this other particle doing? And what if this particle sees this other particle moving faster than the speed of light? Now, this particle is going to see this particle doing something that changes the physical effects. This is why relativity breaks everything. Relativity isn't the solution. Relativity is the problem. Relativity is the thing that breaks all of this stuff that allows free energy to become real. >> You combine this equation with Faraday's law. So you take the curl of this and curl of E is minus the PDT. So you get the induction equation. So this equation tells me how the magnetic field will evolve in a plasma subject to flows plasma velocity U plus resistive diffusion. Okay. So without this term this is nothing but the diffusion equation like the heat equation. But this term is quite interesting uh and it gives rise to non-trivial behavior of the plasma of of the magnetic field in a plasma and in particular can lead to amplification of that >> boom baby. I I mean how many yatsi moments chat? How many yachts moments can lead to amplification of the magnetic field? He just talked about how where are these magnetic fields even coming from? He says it seems like these magnetic fields are coming from plasma from nowhere. If the magnetic fields are coming from nowhere, then clearly we can amplify them. Where are they coming from? You know the answer. The answer is the zero point energy. The answer is the ether. That's where the magnetic fields are coming from. And what it means is that if the magnetic fields can come from no from nowhere, there must be a reservoir of energy. Exact thing that we've been saying. And that would mean that fusion has a direct connection to zero point energy. It's tapping into zero point energy. The same way that a oil well pumps taps into the oil underneath the earth that we don't see but it's