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As a blacksmith, the Curie point is one of the most important temperatures to learn, in most cases steel has to be above that temperature in order to quench harden it. When the hot metal is rapidly cooled it locks the new structure in place.

Best video about 770°C I've ever seen!

That demo of the curie point at the start was absolutely brilliant. Letting the bit _cool down_ with the magnet already nearby, so simple, and absolutely mind blowing.

I really admire Jade's ability to take subjects that don't get a huge amount of attention in popular science and make them both intuitive and compelling, especially when it comes to demystifying thermodynamics. It's so easy to hand-wave entropy as unknowable science magic, but I think what makes it a really fascinating concept is that it's rooted in things that are mundane and familiar and yet has such profound and far-reaching implications.

When you said "scale invariance" I immediately thought of fractals. I'm not entirely sure how fractal geometry fits into all this but I suspect it does.

I'm actually writing my PhD thesis on the mathematical modeling of one of these ising models. I've been analysing quite similar phase translitions and seeing your visualisations is really neat. Well done video

Another application of the Curie point is in rice cookers. As long as there’s sufficient water in the rice water mixture, the temperature will not rise above the boiling point of water. But then once enough water has evaporated the temperature rises and the Curie point of a magnet that activates a switch so when it rises the switch opens and cooking stops. Very simple and reliable way to mass produce affordable and reliable rice cookers.

You really took this to another level. I started watching and almost stopped because it seemed like it was more geared towards kids learning about magnets, and then phase transition, then entropy, then you blew the top off my mind. Loved it. Maybe you should put a notice at the beginning so people stay to the end. Everyone who thinks they know something should watch this to see how little they really know.

The patented Jade Hair Whip Cut is as iconic as the Vsauce Michael Stand Up Entrance

The old Weller 'Magnastat' soldering irons used this principal. The back of the tip had a slug of alloy carefully blended to reach its Currie point at a specific temperature. Back in the handle was a magnet on the end of a Steel rod. This would be attracted to the back of the tip and when pulled forward, activate a microswitch supplying power to the heating element. The microswitch would also act as a return spring. When the tip reached its desired temperature it would no longer be magnetically attractive and the rod and the switch would open. Very simple and reliable, but to change temperature, you have to remove the tip and fit a different one.

Why do you look so joyful when you talk about these topics? It is contagious! : ) Awesome Video!

16:04 It is incredible how nature is so wild and unpredictable, yet it follows the same patterns and mathematical laws everywhere.

I hope you find a lot of success. You're a fantastic science communicator--striking a great balance between explaining things simply without talking down to your audience. And you know what you're talking about. I wish this were more common. Bravo.

0:41 NICE!!! Worth the forty one seconds. Hey, I'll watch the rest.

0:39 weird how it happens so instantly. I would've thought it would tip upwards before sticking to the magnet

Jade is totally awesome! Love this channel for the engaging manner in which she shares information. Elle est tellement chouette! ❤🎉😊

i am a drainage engineer. i often find it instructive to observe traffic flow to better understand my job. and my job often provides insights into why exactly traffic conditions are the way they are. obstructed flow vs unobstructed traffic flow is very similar to subcritical vs super critical fluid flow. also potentially similar is air flow below and above mach 1, but that's speculation on my part. as a drainage engineer in a very flat terrain, i often have to think about flattening the peak (of a hydrograph) as it moves though the system (usually by providing storage). i did not understand that as well as i do now until we had to "flatten the peak" during COVID. excellent video!

What a great video!! If I'm not mistaken, Ising models were also the inspiration for Hopfield networks, which are a type of artificial neural net that were essentially responsible for bringing the field of connection-based ML out of it's so called "AI Winter". Had not known what the Ising model itself was though, till now!

Maybe Jade will get to this, but I think this I learned that this is how cheap rice cookers work - they have a magnet that holds the circuit open until the water is all boiled off, at which point the temperature starts to rise and basically deactivates the magnet, causing the click off when the rice is ready.

A fractal at critical temperature! Amazing!

thanks this has given me a way to describe the interaction between several complex systems (completely separate from anything you mentioned in this video) and how they produce a tipping point in behaviour.

I wonder whether it would be feasible to build a tiny artificial neural network using ferrite cores. I think they have everything - a step function (above a certain magnetization it flips polarity), weights (relative number of magnetization winding turns) and bias (total number of turns). Even negative weight is possible with counter-turns, if that's useful. It could be trained artificially, but then built physically.

When the screwdriver moves on its own, you're screwed. Great video, Jade! Cheers! 🥰🤓😍

5:23 Jiggle the dipoles - good name for a band 😂

There are so many wonderful reasons to love Jade, Up, and Atom, but I found another one in this video. Jade chose to discuss the dispersal of milk in the civilized and tasty beverage of tea. I hate coffee, which can be quite an inconvenience in the United States. I recently spent some time in the hospital for tests, and despite requesting tea for every meal, I was served coffee with nearly every one. This week, I attended a conference in Washington, D.C. and the venue ran out of tea bags before lunch. Thank you, Jade, for the fascinating and informative video, as well as the tea reference.

Everything is emergence. Excellent video, thank you.

This is easily one of the coolest intro clips on YT. Just get to the point by going "watch this". THEN get into why. That is so effective, I was glued to my screen lol

One of your best videos ever. Always good to see a new video from you.

that scale invariance demo is pretty fascinating

@10:46, The answer to Why it works with so many things is: "The power of Assumption." Man always assumes he knows something when in fact he only ever makes himself and and in some cases possibly others believe that they actually know what's happening. Anything that is supposed or imagined is not REAL. All Math is Supposed so it exists outside of Reality. Therefore, you can not Prove anything with Math. While it is true you can solve your equation, you can not solve Reality because it will never exist within your equation because of the infinite number of ignored variables you choose/have to leave out of it.

i love how my first thought when presented with the Ising model was "this looks like it would be interesting to model in a cellular automata".. imagine the smile on my face when the video hit 6:05 😄

You're great Jade.

First time seeing one of your vids, I love how you visually reinforce all important things so clearly, I feel like I'll remember all of this so much better than I otherwise might! Awesome video overall, thanks for sharing!

Looks like it was your magnet that lost its magnetism from the heat first. Neodymium magnets are highly sensitive to temperature in my experience. You can see the carabineer fall at nearly the same moment as the driver bit. The carabineer is aluminum so non-magnetic however the spring inside is steel.

The German name "Ising" is also a small monastery next to lake Chiemsee in Bavaria. In that case the letter I is pronounced like E in English. So it would be pronounced Eseng in English. Ising is definitely a German name. Great video and explanation!

I've just finished my course in statistical physics, and the timing couldn't be more perfect :)

Another thing to keep in mind is that even if it is a gradual process to become magnetic, as soon as the point is reached that it is strong enough to overcome gravity, the object will start moving towards the magnet, which increases the effect of the magnetic field due to proximity and therefore speed up the object towards the magnet. It would be very interesting to put it on a scale whilst being heated.

4:10 another issue I have. These are not low energy materials. They are balanced materials. The energy is the same. It's just if they are aligned or not. And thus you notice it or not. In a random situation, the different polarities counter each other and thus you don't notice any impact by the material.

Good, insightful video. Many thanks. But a slight correction at 04:00. A ball falling is NOT an example of system wanting to go to a "lower energy level"; That motion is entirely governed by Newton's 2nd law and other equations of motion; During a fall a ball's total energy does NOT change; It's merely converted from potential to kinetic. And this falling is unrelated to increase in entropy (and can occur for a single isolated object for which entropy is not even well defined); The diffusion of all that kinetic energy when it hits the ground (has stopped) into the environment, is through an entropic process (2nd law of TD). But gravity is not en entropic force (AFAWK); Neither are E&M, strong and weak forces. In other words, a ball released from a height, falls and does not go up, NOT because of the 2nd Law of TD (that it wants to have its energy more evenly distributed); But because of ball's initial state (condition) and also the phase-space flow of the Newton's (differential) equation (and other differential equations of motion based on minimization of action). But for many other systems of multiple entities (e.g. a hot iron rod cooling or dipoles re-aligning) their total energy actually decreases and it disperses into the environment (e.g. as IR photons); For the hot-rod cooling, it's driven by the diffusion equation which is an entropy-related result. Thank you again.

I sometimes still think of Up and Atom videos as they were when I first started watching: Excellent potential and still a bit rough; somewhere along the way this has become a top-notch mature channel!

I don't have a background in physics but I am doubtful about the magnet demonstration being the correct. Take the following two cases: Case A: There is an iron slab lying on a wooden table and someone places a magnet far from it and then slowly nudges the magnet towards the iron slab. There will be a point where the magnet will suddenly snap towards the slab. Case B: The experiment performed in the video where the temperature of the slab is lowered to 770 C (from > 770 C) and then it suddenly snaps to the magnet. In both cases we see this sudden snapping between the materials. Upon reaching 770 C, even if the material were to again the magnetism slowly, I think still the same observation (sudden snapping towards the magnet) would be observed, probably at a slightly lower temperature though. So perhaps this experiment does not demonstrate the Ising model. Please correct me if I'm wrong.

This is probably my favourite video from you. Really good and easy explanations!

well i havent seen one of your videos for ages!!! love your content Jade!

Thanks! I love your layman’s terminology. It helps noobs to science like me grasp these concepts faster.

The energy minimization dominates in all cases, not only at low temperatures. The second low of thermodynamics is looked in the wrong way, a system moves to high disorder, when applied heat, in order to maximize its energy emission (of the build up energy), or put in another way, to minimize the resistance to energy emission. So in this way, the leading natural principle is ALWAYS the law of least resistance (which is quite profound, when one understands it) This line of thought is actually noted in Heaviside's Electrical Papers, when discussing heating and cooling bodies, but is virtually unknown by the scientist due to its burial deep in the not-so-known-parts of the papers.

I remember being initially baffled in my engineering Materials courses by the presentation of "phase diagrams" for solid materials. In regular thermodynamics, the solid/liquid/gas phases were easy to grasp, because melting solid water into ice at a constant 0 C and liquid water into water vapor at 100 C was something one knew from childhood. But what "phases" even meant in a solid material was never introduced in the same way. It took me a long time to figure out what it all meant, and then it was very satisfying to apply that knowledge to engineering materials. My engineering degrees are from Purdue University, and I think they really didn't have a very good academic program in material science at the time (the late 1970s). A presentation such as yours would have really opened up my eyes had I seen it at the freshman level, and I would have made much more rapid (and/or less painful) progress in my education. I've been back to Purdue recently, and I think that the students are far more advanced than I was at the same age. It would be interesting to see how videos such as yours have contributed to that.

If I could convey concepts as well as you, that would like solve 70 percent of my problems. Good stuff.

As an audio engineer I made a connection to dipoles in one direction to the phase of audio signals being aligned or not, there is a kind of phase transition where the imaging and overall timbre of signals from different sources become a single, balanced field of frequencies, where suddenly everything sounds "glued" together rather than just hanging apart, at least when recorded & mixed well! (A common idealized model of that balance is simply pink noise.) I don't know if there's actually any kind of a relationship between dipole direction in a magnet and phase alignment in audio, and you don't have to have the phase of all signals aligned to make your music "magnetic", in fact it's sometimes more musical to play with phase, but this was a fascinating video and had me thinking in interesting ways, thank you, Happy Thanksgiving to all, take care

I am so glad you're making new videos! Keep up the great content!

4:32 This illustrates the zeroth law of thermodynamics, which states that the entropy (disorder....kind of) of a perfect crystal (something with an atomic structure that repeats itself perfectly...more or less) is zero at a temperature of absolute zero. But I got a D in thermal physics so take that with a grain of perfectly periodic sodium chloride

I always love your videos and find them educational. This topic was a little easier to wrap my head around, and that's not a reflection on your presentation. And I'm always fascinated how a principle can have parallels or applications far beyond its specific one.

I love the quirky and well-researched videos you put up! If I was a physics or science teacher, I would include your videos as part of the curriculum/homework! Note, I would've loved watching your videos and tutelage when I was young and in school! Thank you for your videos!

My first thought was how 1/137 keeps showing up in physics in different seemingly non related interactions.

Brilliantly clear video. You're really at the top of your game at the moment, keep up the good work!

Jade, its great to see you looking happy and interested in this fascinating topic. Phase transitions are both abrupt and repeatable enough to serve to calibrate temperature devices for example. You can validate the readout on a meat thermometer by placing it in boiling water (uncovered pot at sea level). When the water is boiling your readout had better display 212 degrees F or 100 degree C. Carefully prepared ice baths provide another calibration standard at 32 degree F or 0 degrees C. Cool video- that screw driver bit changes its mind in a big hurry!

This is a different view of a fundamental phenomena that I think is endemic to all complex systems. I was first introduced to the phenomena with the book "Linked: The New Science of Networks". A wide variety of different kinds of networks exhibit this scale invariance property. This is also related to phenomena like Benford's Law.

Wow. That really opened my brain. I see this effect everywhere. It basically explains why negative attack adds work so much better than someone explaining why such and such is a good idea. The attack add creates negative energy (my opinion) that spreads more easily from human to human since we still have an inherent flight/fright bias. 👍🏼👍🏼

11:37 does this require actual simulation or can this specific state be written down mathematically? Could be pretty useful as a noise pattern for digital artists

Great sound effects. And fascinating content. I may have to listen 2 or 3 times. Solid-> liquid and liquid-> gas transitions involve enthalpy (or latent heat) of transition wherein there is no temperature change as more energy (heat) is accumulated. Anything analogous here or in other phase transitions? After the mention of Drosophila earlier, was your pun, "fruitful", at 9:45 intentional?

This is a tour de force. Teases us with the “wouldn’t you like to know how all these disparate phenomena are connected?” and then pays off in spades. You connected a lot of knowledge dots for me! And a lot of comments are saying “mind blown 🤯” which i suppose is saying you have induced a state of childlike awe and wonder about the Universe. Kudos and thanks! 🙏

Gorgeous video, Jade! 🤩😍 I felt that special "whoa!" in my mind as you got to the pattern of scale invariance. Awesome and fascinanting!

If you very very carefully controlled the temperature at the exact critical temperature / pressure could you theoretically obtain levitation?

Dipoles flipping seems kind of like the game of life thing, but with a slightly different set of "rules"

Found you recently due to the algorithm. Love your content! You're like Vertasium, but a fellow Aussie.

As an electrical engineer we encounter the curie temperature when working with ferrites. It is a metallic crystalline structure that is used to make the core material of certain inductors and transformers. The permeability increases in a material up to the "curie point", then it becomes paramagnetic and the permeability 'goes away'. In some materials that phase transition is permanent, and even when cooling the permeability of the material does not return. This becomes most apparent in an electrical device known as a 'balun'. This is a type of transformer used at high frequencies (RF for radio) and baluns are used to transform impeadance to match radios to an antenna. Running too high of power with too small of a balun, with too great of an impedance mismatch will cause significant heating and the ferrite may cross the curie point.

WOW! One of your best videos! It feels like this is brushing up against the phenpmenon of emergence. Very cool!

If I am at 770c, I would be dead. That would be the weirdest thing that ever happened to me.

The cooling bit makes a dramatic demonstration, but it doesn't conclusively indicate an abrupt phase transition. A gradually magnitizing bit would also jump suddenly to the magnet due to the inverse square law. Once it gets pulled a small amount closer, the reduced distance increases the pull strength amd it immediately jumps the rest of the way.

I've had a bit of a crap week and it just completely brightened my day to have you teach me this. A very interesting concept that I was vaguely aware of but had no idea it is so widely utilized. Thank you so very much and I hope you are doing well 😊

Materials phase conversions are fascinating. Is why metalworking is so much fun.

One example of universality is how statistical mechanics and thermodynamics can be used to describe economic phenomena. Money distributes among individuals in a society the way energy does particles in a closed system. Supply and demand is a simple version of potential energy stored in a concentration differential across a membrane. You may wonder why you haven’t heard of these examples before, and it’s because economics isn’t a science so much as pseudoscience to justify capitalism. As a former advisor for the Federal Reserve called it: “apologia for the rich”

2:26 Is it the permanent magnet on the left that lost his magnetism from the heat, or the metallic thing becoming magnetic because it's stuck on the permanent magnet? And does a permanent magnet , after losing his magnetism from heat, returns to his original magnetic state when cooling down?

Awesome demo at the start. As an amateur hobby knife maker I use a magnet on a stick for this reason to know when the steel is in the austenite phase.

In the first minute I blurted out percolation and thought I knew what this was going to be about, but I'm glad I didn't skip. I learned something new I didn't know about universality classes, or that percolation had a different exponent. Can you do another video exploring other universality classes and what in the real world they relate to? Then maybe you can get three blue one brown involved and he can show what makes those emergent properties come about the way they do. Thank you for another good video.

As a professor of fluid dynamics, a flow almost never instantly changes from laminar to turbulence. It can appear that way but it will always have a transition. Maybe I'm missing something.

So room temperature semi conductors can only be achieved if the thermal energy of room temperature is lower than the crystals structure interactions that keep the molecules below their curie point.

Science. At one time, was taught like this everywhere in American public schools. Excellent practical demonstration with huge applications !

Nice video, clearly explained and easy to absorb the concept. I will need to read up on power laws, as I can see something it might be useful for: Modelling Emergence.

Thanks!

Thank you again for the great video 😁 I never really gave this phenomenon any attention. Not sure if I didn't remember it, or if I was ignorant of it. Either way, I find it extremely interesting. It's almost like when Hannah Fry developed predictive algorithms based on other phenomenon. She discovered that certain unrelated systems tend to behave similarly. Here, we see pretty much the same thing, but in a little different manner. I'm really glad you've continued on your science communication journey. I can definitely appreciate the sense of wonder and excitement you give to what you are looking at. It's inspiring.

@3:17 one of your arrows near the bottom left corner is going the wrong direction or colored incorrectly.

Wonderful video as usual! I really love this recurring theme of yours where you show links between things we'd never have thought are related. I feel like knowing about these kinds of relations adds new layers of interest to reality, which is great. I'm not totally sure I understand the social networks example. Is it like, say, in normal times most people are pro vaccines, but when something like covid makes the subject extremely trendy then lots of people will change their mind all at once and become antivax because opinions reach way bigger audiences than usual? I guess the point where I stop seeing the analogy is that in social networks as far as I know we tend to observe extreme polarization; i.e. contrary to dipoles nobody is changing their minds again once it's been changed once. Unfortunately I don't think we observe a phase transition even once the "heat" of the subject is removed. Lots and lots of people are still antivax ;)

Great thumbnail and first minute! Bravo!!!

I like your videos, I always learn something new and they always hit a sweetspot of complexity for my science litteracy level!

But isn't the reason for the magnetic characteristic of steel it's crystal structure? Ferritic phase is magnetic and austenite isn't. You can also meassure the volumen and you would see that it shrinks a bit at this temperature cause the atomic packing factor changes. By the way if you add enough chromium to a steel-alloy it's in austenite phase regardless temperature

Curie point. I love this subject. Thank you for making this

There are a few models of Weller soldering irons use a curie point to regulate it's temperature. The tip has a special magnetic alloy bonded to it. If the iron is below about 700°F, a magnet inside is attracted to the special metal and pulls on a switch, turning the iron on. If the tip is above the curie point. The magnet will not be attracted to it and the iron will be off.

Nice, 60 years ago I learned this at school from a teacher that worked at a steel plant. They were hoisting hot ingots when the gripper broke down. They put a electromagnet hoist but that didn't worrk. Steel plant in Holland, Ijmuiden, production line was Westinghouse teacher went before 1940 to USA and spoke there with Tesla as he told us.😊

From Curie to James Hoffmann 😉 Curie point is widely used in simple (Weller) soldering irons to control the temperature. You can get tips with different temperatures due to the piece of metal on the other side having a specific Curie temperature.

Fantastic to see the return of the sound effects whenever you turn around.

Excellent demo! I haven't heard of the ising model before. It is fascinating. How do the dipole magnets align each other? If they were each NS aligned, then they would attract the opposite pole, mixing them all up. I suspect it has something to do with the scale invariance you mentioned. So interesting! Thank you!

Hey @upandatom, do you think the coalescence of the behaviour physical systems, measured by complexity vs. simplicity of mathematical formulas modeling that behaviour, at certain scales and energies can be compared in any way to a state change? I've long wondered why chemistry and Newtonian mechanics at "human" scales seems vastly simpler than quantum field theory is at small scales, GR at large scales, both of those together at extreme energies and settings like nearby and within black holes.

I just started the video, and remember making pendulums out of older Canadian nickels (which were actually nickel!) and a torch. A great science demo from the sixties. Nickel has a much lower Curie temp.

Very well explained! You're really good! Question: what plays the role of Curie temperature in a neural network?

A cool connection that hit me when you were showing the appearance of a system in transition and zooming out. I was thinking casually about how the pattern reminded me of like diorite or any other phaneritic rock grain, and it hit me that I'm pretty sure the resemblance isn't actually trivial: phaneritic rock gains that texture because the slow process of differential crystallization that forms them proceeds spontaneously from nucleation sites in a manner that is directly comparable to the spontaneous ordering of magnetic domains below the curie temperature, and idk I though that was really cool to think about :3

Thanks for the great detail and awesome delivery. I'm incredibly curious if it's just temperature or if any energy would cause similar effects. An easy way to test this would be to pass a current through the object and see if the critical temperature changes. Granted, conductance is more difficult at higher temperatures but plays directly into E living in the same domain. I've got a strong feeling that all forms of 'E' live within the same domain that share the same limitations. E=MC^2, F=MA, W=VA would all directly correlate changes in E, in parallel, along with changes to all E limitations and critical tipping points (if the E was extracted from those 3 dumbed down equations). There are many, many more equations that would be inclusive of E.

I love the energy and attitude in all your videos.

This is a great video and I learned some cool stuff! And I’ve taken advanced classes on this and have a PhD in physics😝

Love natural switches and was looking for some explanations so great video. Now to apply.