If you have a single atom in a cubic meter, that plasma will cover the whole cubic metre! Two, three core layers, rotating layers, used for a difference in the system for high-speed, and what we call, "protection", like in the cosmic dusts.... ...like in the cosmic dusts. You use your reactor so the first two inner cores maintains your gravitational-magnetic field, the third and the fourth, you control with your subsidiary reactors, for shielding in the direction of strengthen. So, what you do, is you bring in your third, which works on the outer boundary, and you use one of your 120 degree reactors to strengthen the shield in the direction of the motion. So, you have two layers, this is part of the difference. And I'm sure the Iranian government uses it in their space technology, especially for capture and landing, you have to maintain your gravitational, but you increase your direction with your third and a fourth reactor. This is very important when you, when you travel into, or you create a variation magnetic field testing, that you can get away with the first shield; use a central core plasma. Central core plasma, very much like a sun. Then you have to know how to create little layers of magnetic field in your plasma core. You do it in a specific way, through different materials. Scintillation does not just come in hydrogen, or helium. In the body of man, it's done by four different elements. In our amino acids, so if you learn that, you can convert it into practical reactors. But the glass tube you have there is very, very interesting. I've seen the guy what he is doing on the internet; he shows a plasma, and he plays with it...it's an American guy who's recently come on the scene. The Primer Fields, I think that is called, is that correct? I don't know...I've seen one of his videos, it's a nonsense. He literally... when we were talking to you, it's like a globe you have in the back of your... on your, what do you call it. All he is doing is... he is making a glorified version of this...Yeah! We used this in labs in physics. in secondary schools, so what he has done, he creates a what he calls a plasma, and he puts current through it. So, it shows the light. Or, he says this is a plasma and this is what I'm doing with it. This is something that's been done in the 1950's! It's been done in the 1910's and 20's, even then they were experimenting with high voltage, and showing that the effects of the galaxy are created by doing that, you know. You don't need high voltage. You don't need high current. Yeah, it's old news. If you look at the video we put on our Forum about our reactor, and if you look at the power supply, we use very, very little, very little. About 150 volts, is the way I was reading it...is that correct? No, no, no, we don't... The system maximum uses...we use a 9-volt battery, a rechargeable battery, to run our operation in testing. You see, when you do a rechargeable battery, you connect your battery to your motor to start your running, and then you take the energy from your reactor once the plasma is created, to recharge your battery. So, you become supply independent. This is how you isolate from control from outside. If you have a power supply, you have a line connected going through your shielding, let's say, and you can't have that. Simply, look at the Columbus, the Shuttle. When they come back, and they come at the wrong angle, they give in to burn. If you create a field, you have to maintain control of it internally. Because the shielding will not allow you to go anywhere else. You become isolated, you become insulated. So, we have chambers built internally, we have even gas chambers built internally, for control and feed. You can not work with a cable power supply. You have to build your power supply internally as part of your reactor... Yes, we've been, say, "playing" with that high-voltage thing, just to see different effects, and see what happens. Like we take a Plasma Ball, which when you hold it this way, with its little column in the middle, it looks almost identical to your patent, actually. I can actually hold your patent up here...I don't know if you can see this... And I hold this right in front, and it matches exactly the patent... Yes, well look at the drawings around it, there's a lot of information in that drawing. You bet, yeah. But it's interesting that the gases inside this little Plasma Globe are inert gases, many of which are the same as in your reactor, so that's why we started, sort of...I got the idea, anyway, to start playing with a Plasma Ball, just to learn more about it. What happens to a Plasma Ball when you put it in a vacuum? What happens when you spin it at 4000 rpm? So we did those experiments, and... And what were your results? Well, when we spun it, You see the central tendril is forming, there now, at 1000 rpm or so. I'm going to rev it up... So, we have this Plasma Globe... It's got the gases inside. What gases do you have in it? Well normally there's Argon and possibly some neon, and... other gases along that same range, possibly some helium, depending on the colours in each particular Plasma Globe. Apparently quite often they use Argon, and Xenon. This is something you bought off the shelf? Yeah. You buy this for like $14, and it's got... Yeah, Yeah, I thought you made it yourself. ...It's got a high-voltage power supply all ready to go. No, that's the thing about it, it's already made, in fact I've already taken the bulb, the glass part out of the bottom, and we put it in inside of a vacuum chamber that I made here. You can see the bulb sitting inside there? Yeah, yeah. Then we run it with high voltage from a automobile coil system, you know, with forty, fifty thousand volts and so on, and...in fact, well, we could try it here right now, actually... just to show you what it looks like. You get a purple plasma happening inside the chamber, basically. What colour was it before? Well the ball itself will be... like a normal...it's normally this colour with tendrils that are blue and so on. Go ahead and turn the vacuum on there... okay... Just a second, here... This is what you call a "Live Performance?" heheh. Yes, that's right exactly! We like to change things on the fly. Last week we probably changed the chamber a hundred times and tried a hundred experiments in a couple of hours... you know. Do you want to get ready with that light? Okay, I'm not sure if you can see that...we might have to lift it up... It gets a little dangerous! Oops, we lost the connection! Can you turn the power off? Yeah. Kill the kitchen light there, Paul. I don't know...can you see that at all? Kinda dark... It's bluish something. Yeah, it's bluish and purplish inside there, We can actually move it a little closer into the circle though, Oops, the wire is off! Watch it! ...Hmmm, Rick? Yeah? ...Mr Keshe can not hear us... Hmmm... I'm back, I'm back, I'm back! The minute you touched something, then you got off, it went there. Maybe it was some of the high-voltage might have affected things, it's entirely possible. It will kick out my cell-phone when I get it too close! Ok, sure we can try that again here... Uh, we're going to have to kill the big light...Yeah, I know... Ok, turn it on... Ask if he can see anything. Can you see anything there, or is it too dark? It's too dark...yeah, I see the plasma, in a line now... Yes, it's just starting to get going there now, as the pressure drops. How come it is not like before? I don't know, it's different this time... So, depending on some of the...There ! That's a different effect now, then when it's at a very high vacuum. It just takes a bit of vacuum that's less to create a totally different sort of phenomenon there. Pardon me? Do you understand the reason behind it? Well, I understand that the, ah, plasma changes with the pressure quite a bit in terms of the way the... You have a gas tube inside. The pressure doesn't...has nothing to do with the pressure. When you vacuum the system, literally you reduce the number of elements inside, so you allow the plasma of a proton, of what is inside the chamber, to open up. So, your plasma inside the light, connects through to the energy or magnetic field of the gas element which is outside it, which you remove, so in fact it's a connection of magnetic fields that allows the different, what do you call it, different shape of the plasma. The more you extract, ...it's just like a balloon, it opens up more, so the plasma is freer. This is how you generate electricity, or power. You, when you create the vacuum, You allow one or two, or let's say a very limited number of plasmas or atoms in, you strip it, now you play with the game. This is a very nice way to show the opening of the plasma. Here, in the normal condition, when you are not a plasma, it is like having twenty, thirty blankets on top of you! Exactly! When you take the blankets away, the plasma which are left in there...There is no full vacuum state in the universe. Right. The word vacuum is a wrong word in the vocabulary. There is nowhere in the universe which some magnetic fields are not traveling through it. And even having hydrogen atoms and so on in every square, or every cubic centimetre...there is a few at least. That single...if you have a single atom in a cubic meter, that plasma will cover the whole cubic meter. Yeah? This is a hard concept to get our heads around. No, no, no... But I understand what you mean, but it's a big one, The plasma behaves exactly like a gas. The behaviour of the plasma is exactly like a gas. It fills it's container. Do you understand? Yes, definitely. So when you reduce, when you take so many atoms out of your cylinder, You allow the very few plasmas which are outside the tube, to open up. And in opening up, you allow the energy transfer across...