Nitrogen is everywhere. It's a fundamental building block of life. It makes up 78% of the atmosphere,
AND it's in these tiny micro bubbles, in my Starbucks 'Nitro-Cold Brew.' And yes, this episode is sponsored
by Starbucks. They challenged me to liquify
nitrogen out of the air, and that's what I'm gonna be doing in this video. But first I'm gonna try Nitro Cold Brew
for the first time... [Drinking the nitro cold brew] Mmmm It's subtly sweet without having to add sugar, and obviously it's cold and frothy, and I'm gonna explain why nitrogen
makes this possible. But first I'm gonna try to liquify some nitrogen for myself out of this atmosphere. Come on, let's go. Okay, in order to make liquid nitrogen, we need a way to make the air really cold. And to do that, I'm going to use this cryo-cooler. So essentially what's inside here is a
cylinder of helium and a couple pistons. There's a piston that compresses
the helium down into this section, and when it does that, it makes that gas really hot. And so, that heat gets ejected to
the surroundings through this heat sink. Then the helium is expanded down in here,
and as that happens, it gets really cold. So it absorbs the heat from the surroundings. So this is the part of the cryo-cooler
that is going to get down to less than -200ยฐC. So cryogenic temperatures. This is the place where we can really
liquify some gas. So, I want to put this to the test and first do a sort of simple proof-of-concept and make sure that this is working and just try to liquify air, liquify the air in this room. This is Allen Pan. Allen is handier with tools than I am, so uuh, I brought him here to help me make
this happen. How should people know you, Allen? Like what do you get into, what's your thing? Allen: I'm a failed Mythbuster, and also I have a YouTube channel called
"Sufficiently Advanced". Derek VO: You may know Allen from
his creations and, relevant to this project, shooting
liquid nitrogen from his hands. [Allen laughs] Allen: I'm definitely breaking your drill by the way ><, that plastic is coming right off. >D: I see that :) I see that.< Did I measure this correctly? Let's see. Does it go in and stop right there- Oh my God! Look at that! Perfect! Derek: So now, let's turn it on,
and you can listen, you can hear it turn on. Ohhhh, the pump is starting. Allen: Its purring. [Elevator Music] This is the moment of truth: been running the cryo-cooler
for about 4 hours. Hopefully getting some liquid air in there. Allen: I bet you 50 bucks there's at least 50 millilitres of liquid air in there. Derek: "50 millilitres." D: Sir? Allen: That's not even that much. Derek: It ISN'T even that much,>< but
I will be amazed if it happens. > Allen: It's like a whole-< Allen: Oh, that- that's 50 millilitres, right there.
Derek: I bring you a 50 millilitre beaker. Allen: Do you feel any sloshing?? Derek: [Whouf!] [Slight sloshing] Allen: I hear something..! >I hear something!<
Derek: Oh ohoh >< oh oh! Allen: I HEAR something. Derek: I can hear liquid D: We have made liquid air. Allen: That sounds like...
Derek: How much have we made? Allen: 50 millilitres..
Derek: Is that how much we've made? Allen: ..of liquid air! Derek: OooohH..! Cameraman: Oh hoho hoh! Allen: 50! 50! Allen: OOOhh! A: Dude, that's 50 ml of liquid air. Derek VO: I know it doesn't look like much,
but to make 50 ml of liquid air, we needed to condense around
35 litres of air from the room. Derek: What's funny to me is I've done
a lot of experiments with liquid nitrogen, but this feels like the most precious... [Allen laughs]
liquified gas that I've ever had because we made it ourselves. There was more than 50 ml. Allen: I know we didn't shake on it,
but you definitely owe me $50. Derek: I definitely do. [Allen erupts with laughter] [Cameraman chuckles] Derek: 'Cause that's impressive from just
a few hours! Y'know, running it for the first time. Derek VO: Liquid oxygen is paramagnetic,
which means it's attracted to permanent magnets. I'm going to use this effect to try
to extract some liquid oxygen. Derek: Something came out.
Allen: Hey, dude, you got it! You got some.
Derek VO: See that droplet at the end of the magnets? To make sure it really was liquid oxygen,
we tested how it affected a flame. Allen: Yeheheha! Allen: So that's 'for-sure' oxygen, that is liquid oxygen. Derek: You can see how the matchstick REIGNITES with the liquid oxygen, and the flame spreads towards
the higher concentration of oxygen. [Allen laughs] [Low-pitched squeaking and chuting sounds emanate from the flame] Derek: Ohh! [quiet Alien Chestbuster squawk/click sounds emanate from the experiment] Allen: Whwch! Derek: There you go, we have made: liquid air. Next step: remove the oxygen,
and just make liquid nitrogen. [Allen wheezes with laughter] Derek: Okay, it is day two and time to scale up. We are uh, moving the cryo-cooler to a bigger stand. Allen: Should I just go?
Derek Behind Cam: Yeah, go for it. Allen: I'm putting a lot of sawdust
into your-into your carpet. I'm sorry.
Derek: [chuckles] That's okay, Allen :) [Allen laughs lightly] [Chugging, whirring and banging spark sounds] Derek VO: To make pure nitrogen,
we need pressurised air. So I've got an air compressor here in the garage. Derek: The pressure of this compressor
is about 10 'atmospheres'. So I'm going to pressurise this line here... behind cam: Now the first thing we've got on the line is... a filter to remove.. water vapour. And to get pure nitrogen,
this is the key component. It is a nitrogen membrane, and what it actually contains is a bunch
of hollow polymer fibres. And so we supply compressed air in this end, and all of the gas molecules try to diffuse out of those fibres because of that high pressure. But: these polymer fibres are made out of
a material that is SELECTIVELY PERMEABLE. It allows oxygen and carbon dioxide and water vapour to diffuse out much faster than nitrogen. And so, those gases actually come out
preferentially through these holes. So what you're left with at the end is a high concentration of nitrogen. And to get the highest purity, what you need to do is have a very high pressure and a slow flow rate, because that gives a lot of time for
those other gases to escape. Derek: Whoo! D: I don't know about this gauge. [Allen laughs] Derek: So what I want to count on the watch is how long it takes to increase the pressure in the tank. Well, we worked it out yesterday and we figured out if it takes six minutes
to fill the tank... at 100 psi (pressure per inchยฒ), then we've got 98% pure nitrogen. Allen: Cool, perfect. Derek: Right, we just have to be very slow
with this tank filling and I don't know if we ARE that slow. We're going to try to check the oxygen levels that have come through this membrane. Allen: Let's put some money on it. How about 50 bucks says the oxygen
is less than 5%. (<5%) Yeah?
Derek: Are you gonna bet that? 'cause I will easily take that bet.
Allen: Yeah. All right Derek: I don't think this went very well
because that was the first filling of the tank, so we weren't high pressure going through the membrane. So I don't think it's going to be... Allen: I think we're getting 95% nitrogen.
Derek: 95% nitrogen So this meter measures oxygen. So we're looking for a number less than 5%,
which I suspect we will not see. D: Huuh. D: Can hear- [BEEPING] Allen: Oh, it going down! D: Whoa!
A: It's going way down. D: WHOA! [BEEP BEEP] Allen: Come on 5%! Fi-
Ohhhh...! There it is!
Derek: Whoa! D: Here we go 99.
Allen: Over 99%, 99.2, 99.3 Derek: Whoa, I am shocked.
Allen:There is no oxygen in this air, baby, it's all nitrogen! 99.5.
Derek: I am so shocked right now! Allen: So we're at 50 bucks for the liquid air bet?
Derek: Yeah Allen: We're at 50 bucks for the oxygen.
Derek: Yeah, you just have made yourself 100 bucks. Look at that, 99.7..! Allen: ..% nitrogen! Derek: This is insane, and you can understand why there would be an alarm if, uh [Allen laughs] you were in a room with Both: 0.3% oxygen. Derek: Yeah.
Allen: I knew it. I told you. Derek: You knew that you would win.
Allen: Didn't I tell you? Yes! Derek: Okay. So we've achieved, I guess,
the second part of this, which is isolating nitrogen from the atmosphere. And now we just have to...
Allen: Get it super cold. What we got to do is we got to put
this thing.. here. Derek VO: For better insulation, we scaled up to a dewar. Derek: That's impressive. Allen: Kinda sci-fi, janky garage, sci-fi
kind of a look. Allen: Go ahead and lower that. You know just squish right on.
Derek: I hope. Allen: I mean that's sealed,
y'know. [Derek laughs] Allen: I think, uh, honestly? We could just turn it on
and see if it works at this point. Derek: Do it. Just letting some nitrogen in there, so that when the nitrogen goes in there,
it'll push out any... remaining air that's still in the tank. Derek: Gonna switch on the 'variac' which
powers up the cryo-cooler. The other thing I need is the fan... A: Yes.
D:This is the fan. I'm going to plug THAT in. That's a cooling fan of the cryo-cooler. We're up to 8 Watts. Allen behind cam: OoOooOh! [More Elevator Music] Derek: Okay, I have been running the nitrogen setup for about 3 hours, and my concern - because the temperature
on the thermo-couple never got very low - was that I wasn't actually making
any liquid nitrogen. So I've stopped the test and I just want to see... whether or not there is anything in here. Doesn't sound like it. [Pant-laughs] Nothing..! Huh. What I think could be part of the problem, I was putting nitrogen possibly
at a rate that's too high. So this is effectively nitrogen coming in
at room temperature. And I wonder if it was just too warm
for it to ever reach the liquifying temperature right here
at the end of the, uh, the cold finger of the cryocooler. So I feel like I need a slower flow rate, maybe a better way to introduce
the nitrogen into the dewar. Not- as- easy as I'd hoped. Okay, my plan is to go with a smaller flask, ..something like this and, we are going to use its lid to make a nice tight seal. Except we're going to cut a hole through the top. Allen: I think it's good enough for this coldfinger. Derek: Alright. Then we're going to try to drill
a hole in the side for the supply of nitrogen. We need to make nice tight seals
around both of those things. So that is going to be the challenge. This is the kind of- the new design here
that we've got. [Allen giggles] Derek: I feel like it's pretty good. Allen: I think it's going to work. I think we're going to wake up, and there's going to be liquid nitrogen in there. [Yet more Elevator Music] Allen: I bet you $160 that there is
liquid nitrogen in there. Derek: I don't know if I'll take that. [Allen laughs uproariously] I'm gonna turn down the cryo-cooler. Aaand.. let's see what we got..? It looks cold..
Allen: Yeah, there's definitely some condensation. So there's something cold in there. What do you see? Both: OHHHH!!! Allen: THERE'S LIQUID NITROGEN! Derek: Haha! Allen: There's like, There's like THIS much.. That's liquid nitrogen! D: We have: some liquid nitrogen out of the air. Allen through laughter: That was so much effort for this much... Derek VO: So, what do you do with homemade
liquid nitrogen? Well, make homemade ice cream. Just a bit of cream and sugar,
and then the liquid nitrogen. Derek: The most precious liquid nitrogen I've ever had. Is it enough to make ice cream? Come have a look, have a look. [DRAMATIC PAUSE] That is delicious. By freezing everything so fast,
because it is... -196 Celsius,
you get really small ice crystals. And so that gives the ice cream
a really smooth flavour, smooth texture. (Can Allen have some?) In a lot of stores, Starbucks too generates nitrogen just out of the air, because- Why not? It's an available resource. They purify it and then infuse it inline into the drink, creating millions of those tiny bubbles. That gives it its unique texture. So nitrogen bubbles are much smaller
than the bubbles you're normally used to: the carbon dioxide bubbles that you find in soda. And that gives this a sort of creamier texture. The other nice thing about nitrogen
is that it's totally inert. So it doesn't react with the drink. CO2 reacts with water creating some acid,
which you might like in soda. You might want a little bit of a sour tangy flavour, but you don't want that in coffee. Hence, the nitrogen. One thing I found really interesting
when they were pouring this Nitro Cold Brew is that you can
actually see bubbles coming down on the sides of the glass! And that's strange, because these bubbles
are obviously less dense than the coffee. They should be rising up to the surface. So why are they doing that? Well, the answer is the nitrogen bubbles
are rising up to the surface a lot in the center of the drink. And so that actually creates a current that
pushes them down around the outside. And so that's why you see those
bubbles cascading down at the beginning when you're pouring the Nitro Cold Brew. So there you have it: nitrogen is everywhere and useful for lots of things. If you want to try out a Nitro Cold Brew, I'll put a link to order it down
in the description. And thanks for watching. [Outro Sound FX]
RIP Grant Thompson, The King Of Random.
It stated that only professionals should do this, but speaking hypothetically, where would one obtain one of these cryocoolers? Hypothetically of course.
Not a single mention of Guinness.
Well this was a cool idea!
I know Derek has explained briefly on the Cryocooler. When the helium gets compressed and release the heat, does the heat release to the heat exchanger and then to the ambient? Is that why he has another fan to cool the heat off the cryocoolerโs body?
Also, when the helium expands at the end, it absorbs heat. How does it stays cool and colder when it absorbs the heat? Doesnโt absorbing heat mean increasing temperature?