Video Transcript
Ampere's law, longitudinal forces, scalar forces, the thing that we've been talking about all this time, they have been proven. So, you say, "Ashton, you're doing the same thing that other people are doing. Why don't you just tell me about disclosure? Why don't you just tell me what they're covering up?" I will, right now. They're covering up zero-point energy. They're covering up an extra dimension. They're covering up the fact that spin spin is connected to can help to assist in unifying gravity and electromagnetism. That's what they're covering up. They're covering up the fact that they can produce real negative energy and thus cancel out Einstein's equations. In fact, let me play this clip first, and then I'm going to go to the next clip. important, okay? On the top, you're going to see normal positive energy interactions. On the bottom, you're going to see negative energy interactions. >> to a collision where one of the blocks has a negative mass. We still aren't worrying about forces at this point. >> Okay? So, >> [clears throat] >> when you interact with a negative mass, look at it goes faster. Instead of slowing down, it goes faster. Can you imagine running into a wall and then suddenly going faster afterwards? That's pretty weird, right? So, this is why negative energy is so important because negative mass or negative energy basically balance out positive energy when it comes to the math. And now, if you take if you scale this up, boom, look how much faster it goes. And now, if you completely balance out the positive and the negative, 5 + 5 - 5, boom, teleportation. Right? This is why negative energy is so important. Negative energy is the workaround is the workaround to the math. This is why there is real free energy. Real free energy that can be tapped into in the form of zero-point energy, space-time itself. Proven by the uncertainty principle. And the longitudinal forces are the stress in the medium. The stress in the medium, I would argue, is our gravitational pull. If I take these headphones and I pull on them, right? There's going to be this stress in this medium. This has actually been proven in electrical wires that what's going on in the electrical wire is not just simple electromagnetism, but that there's an interaction where the electromagnetism is interacting with it itself. And we call this this longitudinal force. Here you go. So, Grenouille has done a very simple experiment. This is new, I think. Where he takes a very simple idea, just a straight wire, and says, "Is there some type of stress that cannot be accounted for by normal classical physics?" Heat, expansion, met- met- metallic pinching, etc. >> To something almost embarrassingly simple, a straight wire carrying a direct current, while temperature and force are measured at the same time. The point is not to create a spectacular effect. It is to remove the usual escape routes. No explosion, no plasma, no railgun. Just a constrained wire, a DC current, a temperature measurement, and a force sensor. A current-carrying wire already has one obvious reason to change its length. It heats up. If the wire is constrained, thermal expansion changes the measured tension. So, the experiment does not simply ask whether the wire expands when the current flows. It asks whether there is an an force along the wire that appears with a current, but cannot be explained by temperature. The wire is clamped between a micrometer control stage and an S-beam force sensor. A thermocouple tracks the wire temperature. The current is switched on and off while the force and temperature are recorded together. The key claim is a separation between the two behaviors. >> You know, one thing I noticed from this you look at this graph right down down here and notice how the scaling up the relaxation and excitation are not the same. Notice how it spikes up quicker, but then it relaxes a little bit slower. That seems like something to me that would be exploitable. When you're an engineer and you see stuff like that, you go, "Huh, I wonder if I can exploit that." It's like looks like it's like when I turn it on, it ramps up very quickly. But when I turn it off, it go it relaxes slowly. It's like, "Wait, so then can I just pump this like uh a swing? And just like keep the swing pushing with little small pulses?" Like that would be your first intuition, right? >> Heating produces a slower thermal change in tension, but switching the current on produces an immediate force offset. When the current is switched off, the temperature falls slowly, while the force offset reverses much more quickly. In other words, the force-temperature curve has the expected thermal slope, but the current appears to add an extra offset. That offset is the claimed anomalous longitudinal force. >> So, what he's saying there is that this proves that longitudinal force is real because you're seeing this extra offset that shouldn't exist otherwise. So, you look at that and yes, whoever just said sawtooth waves, that was one of the big reveals. The sawtooth wave is what you see right here. You see your sawtooth? Actually, no, this one's the sawtooth, right? Yeah, this is the sawtooth wave, yeah. That's what a saw looks like. These are the sawtooth You know what? Holy I didn't realize that was a sawtooth wave until just now. That's the sawtooth wave. Looks like a shark's teeth, right? And you go, "This is the secret. This is what they thought the secret was to potentially producing uh anomalous thrust." I think it was that What was that guy? Hold on. Let me Do I have that other clip? That's This is crazy, actually, now that this is being revealed right here. Hold on. I think I have this. Was it this guy? Uh this one. >> White tested what we call second generation SFE uh as a confirmation effort for DARPA at the time, and they >> I think this is the guy that said that he doesn't say it in this clip, but I think this is the guy that might have mentioned the sawtooth wave. Maybe I'm mistaken. >> they also saw force. Very good force of that. So, uh um so, yeah, we've we've never had a problem proving and proving and that there's a force present. In fact, that's the entire basis of our research. It's like, "Throw away the ion wind. What's left? Why is that thing keep moving? Let's harness that, because that's that's where the money's at." You know, that's that you know, that you know, literally, that's the real deal. Everything else, yeah, it's okay. By the way, the modern term for the ion wind effect you guys are talking about is referred to as plasma actuators, and they're very popular now in the industry. So, >> Okay.