Brought to you by the reinvented two thousand twelve Camray. It's ready. Are you get in touch with technology? With tech Stuff from hof dot com. Hello everyone, and welcome to tech Stuff. My name is Chris Poulette and I am an editor at how Stuff works dot com. Sitting across from me, as always, his senior writer, Jonathan, the Seller of Lightning Rods arrived just ahead of the storm. Wait seller or seller s E L L E er uh.
And technically that's cheating because that's the first line from chapter one of a book, but there is a prologue to that book. But I wanted to use that line because it kind of ties into what we're talking about today, which, by the way, comes to us courtesy of a little Facebook feedback. You and this comes to us from our friend Bassu, who says, Hey, Jonathan, our plasma ray guns possible. I'm waiting for the next podcast on this. Well, here's
our next podcast on plasma reguns. But before we get into the idea of weaponizing plasma, let's talk a bit about what plasma is and maybe some common or at least more realistic applications for plasma that that we used today. Okay, So, so plasma it is the fourth state of matter. Yeah, it's funny to me because growing up, um, perhaps my my school system was narrow minded, although I don't think so. We we learned about solids likewids and gases. Those were
the three states of matter and that's all there were. Yeah, and the pronosaurus was a dinosaur exactly. You know, it's probably because I would guess it's probably more because growing up, plasma is a little hard to grasp. It's I figured out. Literally, I figured up, yes, because if you can't, it hurts. Uh. I'll the way I figure the best explanation would be look at it from the stance of molecular movement. Okay, so with solids, the solids are made up of molecules,
and those molecules don't move a lot. They are moving. So even in that granite table that you might see that the molecules within that granite table are actually in motion, they're just not moving a lot. You can take it for granite that they'll stay put. Yes, And then in liquids you have a little more molecular movement, and the the actual composition of the matter it acts differently. Right,
So ice is a solid. Water is a liquid, and then if you add more energy into the system and you create more molecular movement, you can make that liquid turn into a gas. And in the gas, you've got a lot more molecular movement. The molecules aren't as packed closely as close together as it would be in a liquid or in a solid, and that's when you've got
the gas form. Well, plasma is the next step. It's when you've added even more energy into that that element, and this also tends to strip away electrons ionizing that gas. So you've got free electrons flowing through the gas that an ionized gas that is plasma. So in a way, you can think of plasma is sort of a subset of gas, but it's really its own thing because it's an ionized gas, Jonathan, it strips away electrons. Are you sure? Well, it pushes electrons way out into the outer shells. I was.
I was going for the joke there they lose electrons. Are you sure? I'm positive? OK? No. The reason why I said that is because literally this week phil Plate the Bad Astronomer, wrote a post about ionizing atmosphere conditions and how that creates are the auroras to the Aurora borealis and the Aurora estrallis, and he had written about how it strips electrons away from oxygen and then later corrected himself saying, all right, technically that is not correct.
What really happens is that the electrons are pushed to the further energy shells around the nucleus of the atom, and when the electrons come back down to their natural energy shell, photons are released. And that's the aurora. So that's why I wanted to not do the I'm positive off the bat okay okay, Um, you can tell we
don't we We sort of prepare, but we don't rehearse. Um. It's funny too that that we think about plasmas being the fourth state of matter, and the way it's uh kind of strange because um plasma is far more prevalent in our universe, most plentiful state of matter, of all matter in the universe, all anything that's not dark matter, whether or not that exists isn't isn't totally different subject matter. But that's really too many matters. But yes, of all
the matter that we have observed, plasma makes up. And you might think, well, that's weird be because everything I encounter tends to be either a solid liquid or a gas. I very rarely encounter plasma. Well, that's because you don't live on the Sun. I have encountered a couple of people who have encountered plasma firsthand, um, more than once, because they have been hit by lightning. Yes, and that's what I was saying with my quote at the beginning
of the show. Lightning is something that can create plasmas. Where the ways that we can find naturally occurring plasma on Earth. The plasma does not last very long. Um. But we'll get into that in a second. And I would avoid coming into contact with plasma as often as possible. Now, there are other plasmas that we encounter. Anything, any sort of ionized gas is a plasma. There are some that
are considered cold plasmas. And by cold, we're talking in terms of relativity here, right, you know, it's just it's colder than say the plasma you would find shooting out of the Sun. And then there's blood plasma, right, which is totally different, totally not the same stuff, but like a neon sign that's that's an ionized gas within the neon is ionized within that sign that technically is a plasma it's just not the same quite quite the same thing is what we would find, say a plasma cutter,
which is kind of what I wanted to talk about, because plasma cutter, that's something that's it's a tool that we use that can cut through really sturdy, thick sheets of metal. And it's really impressive if you ever see one of these in action, because you might look at a sheet of metal and you think that, how the heck are you supposed to shape this so that you can use it in various applications like building airplanes. In fact, building airplanes is kind of where the idea for plasma
cutters came into play. Yes, that's that's true. And they plasma cutters not only cut through metal, they do it like butter. Yeah, like butter. I'll give you a topic. Plasma Plasma cutters are are really, if you will pardon my again over simplification, really really fancy because not only are they cutting their cutting very precisely, and they tend to uh basically the way they cut through it, they do it uh in a temperature so hot that it it steals off the metal and prevents corrosion. Yes. Um,
again that's an oversimplification. Let's get into what's really going on here. Sure, So back during World War Two, there was a demand for building aircraft very very very quickly. Yes, and that's that's kind of a problem because aircraft are very complex, very large devices. So that meant that, you know, you had to find a new way to go into mass production. And so there were different experiments being done
about new means of welding materials together. And uh, some folks discovered that if they used a gas and inert gas fed through an electric arc, so they create an electric arc between a couple of electrodes and they shoot gas through that arc, that they could create a very effective welding tool. Now, um, so that was sort of the basis of the plasma cutter. Now, this was not used to cut. This was used to weld, so welding different sheets of metal together, yes, exactly so, uh, but
that that started the foundation. What happened was in the nineteen sixties some engineers figured out that they could actually increase the temperatures of this this uh, this plasma by speeding up the flow of gas and by controlling the diameter of the nozzle. So if they decrease the diameter, they're they're making it, you know, narrower, and they're increasing the flow of gas and they're pushing it through this electrode. It would actually increase the temperature quite a few orders
of magnitude. Yes, And this is where the idea of using this to cut through metals started to come into play. And uh, technically, the typical plasma cutter uses the sheet of metal that it's cutting as part of a circuit. So you've got to think about the parts of a of a plasma cutter. You've got an electrode inside of it, that's what that's what's providing the the the charge. You've got the cutting gas that is inside of it. This is the the inert gas that's going to be passed
through this electric charge and superheated to plasma. And then you've got a controlling gas that's around that that actually is used to help concentrate the flow of the cutting gas. It's it's so you've got the nozzle that's helping concentrate the flow, and if you've got a second gas that's also sort of pushing against that cutting gas, keeping it nice and tight. And then Once you put the the plasma cutter against the piece of metal, then that creates
a circuit. The shock from or the charge from the electrode goes to the metal. The metal has sort of a positive charge to it the and and we know that the negative wants to go to positive, so the electricity hits the metal. The gas flowing through the nozzle is ionized, becomes plasma and superheats and actually turns metal into into molten material at the blink of an eye. And that's when you can just start cutting through it
like it was as Chris said. But yeah, one, when you're reaching temperatures of thirty degrees fahrenheit, that's degrees celsius. That's pretty hot. And when we're talking about increasing the flow of the gas, we're talking this this gas is flowing at a rate of around twenty thousand feet per second. Do you know how many meters per second? That is? Courting on my fingers about six someone's been reading how
stuff works dot com. We do have an article on how plasma cutters work at how stuff works dot com, which is it's a good thing to read about. And if any of this sounds familiar to you, guys, then you've been listening to tech stuff for a really long time, because we did do an episode ages ago about plasma waste converters and what a plasma waste converter is. It's
a really cool application of this technology. It's essentially using a device similar to a plasma cutter a plasma torch to create this incredibly super hot ionized gas in order to liquefy or gasify trash. So, depending upon what the trash is made out of, it will either turn into a gas because you know what's the plasma has applied
to it, or it will liquefy uh. So essentially car carbon based uh elements, anything that's carbon based within the trash is going to gas suffi uh and everything else liquefies and um it's you can use that gas depending on on what you're producing. You can actually use that gas as fuel. And the liquefied stuff, once it cools,
turns into stuff that looks kind of like obsidian. In fact, I have I have a sample of that because when I did the article, I visited a engineer at Georgia Tech who gave me a sample of this solidified waste which looked like it was a volcano rock, which essentially is what it is kind of. So anyway, that's another interesting use of plasma technology. Now let's kind of talk a little bit about the concept of plasma weapons. So we had our listeners specifically asked us, like our plasma
ray guns possible? Um In a word, no, at least not with today's technology. And there are a lot of different reasons for this. One of those is that um plasma, if you were to generate plasma at a at a temperature that would be considered weaponized. So we're talking about you know, hot hot plasma UM. You have the problem
of heat dispersing too quickly. So, uh, the the ionized gas would lose a lot of energy as soon as it leaves wherever wherever you're generating it, right, So at the point of generation, it's going to be very, very hot.
So if I were point blank right up against you and I pushed a weapon against you and I pulled the trigger, then yeah, you're gonna get cut in half, or you're gonna have a whole drill through you, essentially, But if you're you know, twenty feet away, this ionized gas is going to be losing energy at a very fast rate, and as it loses energy, it's going to revert back to a regular gas and you can't really get it to travel very far. And it also disperses.
So if you were to have the ionized gas come out of the end of a ray gun, it's not gonna be a ray or a beam, right, It's not gonna move forward in a concentrated beam. It's going to disperse outward, it's gonna bloom. So in that sense, you also don't really have much of a weapon because the further away the person is, it's it's just like a
shotgun in a way. You know, a shotgun shoots shot and that shot spreads as it goes out, So the further away someone is, the less concentrated the impact will be right right, So same sort of thing, except even on a bigger scale, because we're talking about individual atoms here, not just uh shot. And so that's another problem, um, And there are various ways of getting around this. If you had a gun that somehow could create an electrical charge all the way down to wherever your target is,
it could ionize the gas immediately around the electrode. But in that case you're talking about some sort of superpowered taser. Yeah. Now, if you'll remember, if you think of it as as the plasma cutter, you'll remember that in our discussion on how it worked, just a moment ago, UM, Jonathan was pointing out that the metal that's being cut requires uh is is basically charged. It's part, it becomes part of
the circuit. So if you were shooting at something five feet away, for example, UM, it's going to be very difficult. I mean, you can't circuit. You can't you don't have a circuit. UM. Also, you'll remember that Jonathan was talking about the gas that's on the outside of the pressurized gas that is used to cut UM, that's controlling the the cutting of the plasma cutter. Without that, UM, it's exactly what Jonathan says. You don't have a real way
to control it. And you might say, well what about lightning. Well, lightning it forks it's not controlled. UM. So yes, lightning can can travel a long distance, but it also it's a charge. We know that the ground and the clouds are charged differently. Yeah, it's essentially a circuit. It's a
certually that only lasts a moment. But you know it's not so if you had if you somehow arranged it so that everyone on the enemy's side war of particular suit that should positively charge clothing, so that I could use this negatively charged electrode to create a circuit between me and you. Then I can vaporize you. That would be great. So yeah, it's a little tricky. Um, Yeah, there are a lot of other issues with this, but
there that's not the only way to weaponize plasma. That's you know, that's if you were to have a gun, like in the Halo universe. In the Halo University, aliens have plasma weapons and they shoot these kind of blobs of energy, which you know, essentially it's like uh, blobs of of superheated gas and they travel as if it were a solid projectile and uh like little sunlits. Yeah, these little energy weapons that can do massive amounts of damage,
particularly literally to your shields, right against shields. So yeah, supercharger plasma pistol and then immediately switched to your regular pistol. It's in a great way of anyway. So that's just not viable right now. The equipment we would need to create plasma is much larger than what you could have in a handheld gun and you just wouldn't have those results. But that's not the only way. There are other ways.
Like there's an example, there's a weapon that's been worked on by the US government over the last few years called a pulsed energy projectile weapon or p e P. Now, this creates a uses. It uses a very high powered um laser style weapon. So it's not a plasma weapon at its at its source, right, it's just create it's just firing off energy. It's an inner g weapon. And the idea is that when the energy contacts something solid,
then it creates a plasma. It actually excites the material that it contacts with and that's what creates the plasma. So the plasma is not contained within the weapon, uh, and it's it's just it generates as soon as the ray hits something solid. And then at that point what happens is the plasma that's generated quickly starts to expand
because the energy from the ray is continuing to hit it. Okay, So that expanding plasma creates an electromagnetic magnetic pulse, and this pulse is geared to uh kind of short circuit our pain receptors. And the idea is that this weapon would either paralyze you. It would just make all you know, your muscles contract, kind of like a massive taser, or would paralyze you with pain. You would feel so much pain you would be incapable of doing anything else. This
is the pain ray that people have talked about. And uh, there's a lot of concern in the International commu Unity that such a device would be used not to stop a riot, but rather as a divisive torture to h to really torture a person if you were trying to interrogate them. And of course the whole torture thing has its own issues beyond just the technical but that is a way that people are weaponizing plasma. It's just not using plasma as a direct weapon. It's just part of
the weapon. And there are other ways as well. There are ideas of creating plasma to act as an antenna because they can be much more efficient than metal antennas, and or even use them in anti missile systems, where the idea would be that if you had missiles coming in, you could fire beams up into the upper atmosphere ionized part of the upper atmosphere so that when missiles were passing through them, they would detonate and not land and hit you. Um. So those are ways of weaponizing pla SMA.
That's not not quite the same as having a a cool ray gun. You know, you're Q thirty five space modulator or whatever it's called. I'm sure. I'm sure someone's gonna write and so they know it was a Q thirty two space modulator. Sorry, that was the obsolete person I thought I've upgraded. Yeah, I'm It's also hard to imagine something that shot plasma that would, you know, stop at a certain person. So it would it would shoot through schools, it would seem really it would, yeah, if
it if it were really a superheated gas um. Yeah, I mean, if you were to find some way to control it so that it maintained its integrity and could travel best just distances, then what would stop it from shooting through whatever it was you hit and then going moving on. I mean, it would lose energy every time it contos. But if you're talking about superheated, if you're talking about temperatures that rival the temperature of the sun, UM, it's gonna take a while for that to to lose
enough energy for it to um. If you could keep it concentrated like that, it would take a while for it to lose enough energy for it to stop, which just reminds me of the documentary Real Genius where they fire off the laser and it goes all the way through the entire laboratory and shoots through the head of a statue on the quad. Yeah. So anyway, Yeah, that's that's the basis for the whole idea about plasma weapons. I think I'm not going to go so far as
to say they're impossible. It's just that with today's technology they are not really possible, and it may be that they could be possible but not practical. Yeah, it'll it may very well be that by the time we could create a plasma weapon, something even scarier is out there. So um, yeah, it'll be interesting to see if there's there are further developments in attempting to weaponize plasma technology.
But really, when it comes down to it, it's very useful tech for things in manufacturing and like I said, waste management or potentially in waste management. There are very few plasma waste converter facilities out there. There are only only a couple in the United States, and there are a few in Japan and uh, and that's about it. But but they have the potential to really change the
way we deal with waste. I mean they could they could actually help reduce landfills because most of them have capacity so great that they would be able to serve not just the community on a daily basis, but also take uh garbage that has already been dumped in the landfill and start using that as well. So every day it would be using a little bit more of the landfill as well as taking care of all the daily trash that was generated by the population, plus possibly creating
energy as a result through uh, through using fuel. Um, you know, it's a it's an attractive prospect, but it also requires quite a bit of an initial investment. So anyway, this was going to be a short episode, So hey guys, UH, you're welcome, because a lot of ours have have topped over forty five minutes and a few of them have hit that one hour mark, so you guys are getting off easy today. But that was a great topic. It
was very interesting for us to research. And uh, it's plasma is just cool, not literally it's actually really super hot, but I mean just checking it's neat. Yes, nifty if you will. So, Guys, if you have any requests for topics that you would like us to tackle, let us know on Facebook or Twitter. Are handled. There is text stuff H s W or send us an email our addresses tech stuff at Discovery dot com and Chris and I will talk to you again really soon. Brought to
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