What If You Put a Superconductor in an Induction Heater?
Ғылым және технология
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I show you what happens when you put and type 2 superconductor in a high power induction coil.
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I should add that superconductors can break down in high fields, but I also put it far from the coils so the field was weaker and it still acted similar to steel. This is a YCBO superconductor so the breakdown field should be pretty high. Also I should add that there are more mechanisms that cause resistance in the superconductor in AC fields. Not just the skin effect. I am learning that superconductors aren't so super in AC fields.
@itsdarkhere
Жыл бұрын
@@Call_Upon_YAH okay... does jesus love mario kart and summoner duel or something? I know it's not an issue but I see no reason for channel to contain video games and quote religious stuff at same time but does not upload anything related to it
@barrymccockiner6641
Жыл бұрын
The irony of posting this on a science channel.
@WouterVerbruggen
Жыл бұрын
Good to mention. Especially for these polycrystalline pucks, these critical fields are especially high. Agree that is not really a problem here, see my other comment for what I believe is.
@kristopherhardy3302
Жыл бұрын
I’m curious to see it react w/o the liquid nitrogen 😱🤷🏻♂️. Curiosity kills tho eh? Lol
@anonymouspenguin2647
Жыл бұрын
Cool. Please, make the same experiment with DC current for comparison.
I really liked how you showed the part where you got an unexpected result. It would have been easy to edit that out and have the right answer from the beginning and still explain the experiment well. However, that would miss a critical part of the scientific process, which is encountering and trying to understand unexpected results. :)
@DANGJOS
Жыл бұрын
Completely agree!
@Relkond
Жыл бұрын
Science is less about the ‘Eureka!’ And more about the ‘Hmm, that’s interesting…’ Yes, there are eureka moments, but it’s the unexpected outcome that gets you to look at things more closely, specifically when what’s happening is outside expectations.
@DragonOfTheMortalKombat
Жыл бұрын
This is what makes him and other youtubers different from our science teachers. Teachers make us learn and cram things while youtubers explain and understand with experimentation and uncertainity.
@lucbloom
Жыл бұрын
@@DragonOfTheMortalKombat well, that’s a bit of a generalization. I bet if you ask a teacher stuff after class, there’s enthusiasm to be found. In class though, all IQs need to get to a certain test result.
@JonnyAppleWeed
Жыл бұрын
The experiment was literally to see what would happen. Editing out the unexpected result would have made showing the experiment pointless and the video shorter.
Superconductors are only superconducting at DC. At AC the momentum of the superconducting electrons causes them to lag a little bit, allowing some of the electric field to penetrate. This penetrating field causes the non-superconducting electrons, which are also present, to create a non-superconducting current and lose energy through resistance. At higher frequency, this lag is more pronounced, and more of the electric field penetrates.
@TheActionLab
Жыл бұрын
I couldn't find any information on how much resistance this creates. I wonder what percentage is from the penetrating field vs skin effect. Skin effect could be quite significant in the type 2 superconductor due to the fields around each imperfection.
@Reddotzebra
Жыл бұрын
@@TheActionLab Also, wouldn't the resistance go up when the skin layer is heated since it will heat the neighboring parts slightly?
@kg4boj
Жыл бұрын
@@TheActionLab There is also a maximum amount of current density that a superconductor can handle before it becomes a resistive load to any further current. I suspect this is what happened. This is why MRI machines have to be very carefully ramped up slowly
@T3sl4
Жыл бұрын
@@TheActionLab There's a simple proof of this -- although it doesn't tell you /how much/ at the experimental conditions. Simply consider this one fact: The block doesn't become shiny when cooled. Now, optical and LF waves are quite different; indeed, quantum effects are involved, for superconductors even around far IR. But it remains the case -- and it will be true between both classical and quantum cases (and thus LF to optical), that, at low frequencies, resistance approaches zero, while at optical, it's quite nonzero (black -- absorptive). In fact, your magnet demo at the start, hints at the nature of this effect! In the same way that ferromagnetic materials exhibit magnetic hysteresis loss (energy dissipation upon field change), type 2 superconductors exhibit conductive hysteresis loss (flux pinning). Work is done (you can feel it when you push the magnet into place!) deforming the superconducting path and trapping those flux tubes. It stands to reason, if this is simply done faster -- indeed, a couple ten thousand times a second, say by a few hundred amperes through a coil -- the material will heat up. There are other effects, I think, and also less well understood effects -- even for very pure and cold superconductors -- but this is a very hand-waving introduction to actually a very deep truth: namely, that there must be continuity in the impedance, from DC to (literally) light. The fact that it superconducts at DC, isn't actually much of a guarantee of behavior at AC; but the fact that it's not shiny at optical frequencies, is a guarantee that -- somewhere inbetween -- it will be lossy. The best AC superconductors I'm aware of (and it's been a while since I looked, but probably is still relevant) are made of spun niobium (type 1, no flux pinning), cooled to 2.2K or so, with a Q factor in the 10^8 range -- better than quartz crystal resonators, but still not infinite -- operating at 500MHz or so. These are used in particle accelerators, basically because the bunches of particles have very little charge, macroscopically speaking, so they couple to the applied fields very weakly, and thus require a large multiplication ratio (Q factor) to drive effectively.
@dt9327
Жыл бұрын
@@TheActionLab You should hook the superconductor up to an Oscilloscope and measure the frequency respone. Should be interesting.
I love induction heaters, definitely got a "kid with a magnifying glass" feel with them. Especially cool are the really strong ones that get something so hot they can melt it, but can also magnetically levitate the molten material inside it... that is until you turn the power off and then watch out... that's something the Backyard Scientist would wearing shorts and flip flops.
@Derekzparty
Жыл бұрын
Safety shorts and safety flip flops!
@lordshuv-rowyoknow6486
Жыл бұрын
He wore glasses, that's protect you right?
@gallium-gonzollium
Жыл бұрын
@@Derekzparty Steel-toed Crocs-
@seanramos9114
Жыл бұрын
@@gallium-gonzollium Genius idea from stuff made here
@HeyChickens
Жыл бұрын
@@Derekzparty Hilarious comment dude! Lol
The main effect here are AC losses inside the superconductor, not the penetration depth. The constantly changing field is constantly getting pushed in and out of the superconductor. Specfically, the 'pinned' fluxes are moved around a lot. This costs a relatively huge amount of energy. It is also one of the biggest, if not THE biggest, issue in making superconductors usable in practical applications. Also your puck of ReBCO is bulk polycrystalline. This is great for flux pinning (which is why it's used for these pucks) due to the very high amount of grain boundaries. But in this situation it works against you, as it costs even more energy to move these fluxes around. Even more of an issue is that these grain boundaries are normal conducting, and with a very high resistance at that. You're trying to induce huge currents in something with a terrible transport current capacity. For more information, you might want to look into topics like these AC losses in superconductors and the Bean critical state model. As a sidenote: your steel penny might also heat up so much more because it is ferromagnetic
@TheActionLab
Жыл бұрын
Yes, but what are the AC losses? It has to translate into actual resistance in the superconductor. The magnetic fields that are allowed to penetrate this type 2 superconductor also have a skin depth around each imperfection. So isn't that the same as saying it is due to the resistance from the skin depth?
@WouterVerbruggen
Жыл бұрын
@@TheActionLab It does have to do with a penetration field, but not specifically this skin depth effect. That effect is there don't get me wrong, but it's not the main reason for the loss of energy. You have to think how the superconductor gets magnetized "up and down" all the time. This is called magnetization losses or hysteresis losses. Another AC loss type that happens here are coupling losses, due to current moving between strands or grains of superconductor, so through normal material.
@TheActionLab
Жыл бұрын
@@WouterVerbruggen Yes I see there are many more mechanisms for losses. The bottom line is that superconductors are pretty lame in AC fields
@TheActionLab
Жыл бұрын
Also about the steel penny, I don't think that hysteresis losses (from being ferromagnetic) from the steel penny are the main reason for the heating. I think it is a mainly due to the eddy currents with high resistance. Even at high temps above the curie temps the iron heats very quickly.
@WouterVerbruggen
Жыл бұрын
@@TheActionLab Absolutely! AC effects is the root of many of ours problems working with applied superconductivity. As for the penny, that's a good point. Would have to compare some numbers then to know for sure. I do know some induction cooking pans work better than other due to their stronger magnetic properties. But maybe the effect of frequency is different in those appliances.
This one little experiment illustrates the important difference between theory and observation. It's easy to arrive at conclusions based on logic but we always need to make sure there isn't some variable that was missed in the train of thought. Great video!
@AdityaMehendale
Жыл бұрын
I'm curious to know - what was your initial "conclusion based on logic"?
@jacobopstad5483
Жыл бұрын
@@AdityaMehendale Oh, that was a generic reference to ideas we have about things. But the natural conclusion in the case of this video is that a superconductor should not heat up at all through induction since they have zero resistance. This experiment clearly shows that the conclusion was mistaken. It serves as a great example of how we can take things for granted
@AdityaMehendale
Жыл бұрын
@@jacobopstad5483 I had expected the SC to "jump out of" the LN beaker when the coil was switched-on.
@Thesignalpath
Жыл бұрын
I am sorry, but the statement "This one little experiment illustrates the important difference between theory and observation." is fundamentally wrong. A scientific theory is at the highest level of rigorous understanding of the physical world. It has explained all of past experiments and current state of the world and it can also make predictions about future experiments. If an experiment defies an established theory, the theory would be thrown out and a more refined/correct version would be put in its place. In this situation, the theory perfectly predicts what has been observed. There is nothing against theory here and no surprise at the scientific level. What you should actually say is that: "The observation went against MY expectation because I was not fully aware of the depth of superconductivity theory". Nothing more can be said here.
@AdityaMehendale
Жыл бұрын
@@Thesignalpath Well said, Shahriar :) It's surreal to find you in the comments' section!
👍 good vid. Another interesting aspect of superconductors is they contain "normal" non-superconducting electrons, but the effect of the normal electrons is not observed in DC currents and magnetic fields because the superconducting electrons "short-out" any E-fields that might be produced. However, at AC frequencies the short-out effect is never quite perfect, and normal electrons get to respond and lose energy in the process.
@DANGJOS
Жыл бұрын
That makes sense; thanks!
Having an unexpected result is the best part of this video. It's what science is all about.
6:50 “Super conductors aren’t that super in alternating fields” well said.
an experiment i would never of thought to do, but now i really want to do it myself!
Sheeesh! You have all the fun tools and experiments. I appreciate that you explain details like regular conductor and superconductor. Definitely makes your videos more enjoyable to watch!
You always do experiments that I didn't know I wanted to see.
@trucid2
Жыл бұрын
He's making you smarter every day.
@jobersudyobodou9362
Жыл бұрын
He's making unknown unknowns known.
Now that you explained it and I think about it, it makes sense. A superconductor can have zero ohms as long as the electricity we are passing through it has ANY straight path to get from one side to the other. However, that doesn't mean that the entire block of material has zero ohms. There can easily be some areas with higher resistance due to imperfections in the material, but those imperfections won't raise the resistance, since the electricity automatically looks for the path of least resistance. But when that electricity is being generated by tiny eddy currents all throughout the material, it is much more likely to get trapped between some of the imperfections and be forced to flow through a portion of the material that isn't quite a superconductor. This is my hypothesis anyways. Someone please correct me if I'm wrong.
Love this channel. I've seen the shorts a million times but only today did I actually subscribe. It's nice to see something so educational can do so well in YT.
Interesting experiment! Can’t wait to see the results!
Nice research! Most youtuber gloss over something like this as an error, but I love that you took the time to nail down what must be going on. Respect!
Unless the penny you used was old (before 1982) it is copper-plated zinc, which has a much higher resistance than copper. It didn't get hot because it had too much internal resistance. Try a copper (pre-1982) penny and it will probably get hotter faster than the steel penny.
@vintilk
Жыл бұрын
I came into the comments to say this exact same thing. The penny he used is defiantly a newer one based on the union shield side of the penny. This means that the penny used was 2010 or newer so defiantly coper-plated zinc making it more zinc than copper.
@CarlVanWormerAE7GD
Жыл бұрын
@@vintilk I hope he sees this and re[eats the experiment with a copper penny. As far as the superconductor caused boiling, there are probably some experiments that can better explain that action, too. It would be nice if the RF filed could be adjusted to see if there was a non-linear point that would help explain the results.
@CodeKujo
Жыл бұрын
We don't know the frequency of the induction heater, but they tend to be around 100kHz, which (google...) should mean about 100u skin depth. And the copper on that penny is only (google...) 20u, so yeah, I'm pretty sure that was mostly a zinc penny in that test.
@dx9s
Жыл бұрын
Came to to comments to see if anybody pointed out 'recent' 1 cent pieces are primarily zinc because copper is too expensive. Also heard that zinc "fumes" (heating, burning, vapor, etc.) is on the toxic side and should be avoided, but don't know the specifics of this myself.
@CarlVanWormerAE7GD
Жыл бұрын
@@dx9s I put a small stack of pennies on the concrete floor and then aimed my propane torch at it. The pile collapsed as the zinc melted.
Another reason may be that not everything in that puck is superconducting. YBCO is AFAIK made by sintering, and it's possible that there's a mix of superconductor and "loose oxides" for lack of a better term. For magnetic levitation only the superconducting parts are relevant. The rest of the stuff might be magnetically inert, but in the induction heater the non-superconducting parts might heat up.
Superb. This is one of your best experiments yet! Thank you for this demonstration.
James, your channel is awesome. The combination of broad knowledge in the physical sciences and childlike curiosity is a winning combination. Plus, you show a moment where something unexpected happened - not very common in a science video. Love it.
I believe that the reason the steel penny generated more heat is mainly because there is greater magnetic flux in the steel than in the copper. Same as why we use iron in the cores of transformers. That is why you can only use ferromagnetic pans on induction stoves, in principle you could use a copper or aluminum pan, but the efficiency would be much lower.
@TheActionLab
Жыл бұрын
You are talking about magnetic hysteresis losses. In ferromagnetic materials some heat is generated due to the magnetic domains alternating. But eddy current heat due to the resistance in iron is much more significant than the hysteresis heat created. You can see this is true because even at high temperatures (above curie temps where there are no more magnetic domains) the iron will still heat up faster than copper.
I believe superconductors also will stop superconducting if they're are exposed to too high a magnetic field along with the field changing too quickly. Not sure how strong the field is here though.
@tusharbhudia9421
Жыл бұрын
This! The limiting amount for a good super conductor is about 0.1 Tesla at 0K. With the amount decreasing with temperature. Unless he's using YBCO which can do 120+ tesla
@therealjammit
Жыл бұрын
Saturation effect. It can only hold so many lines of magnetic flux.
@TheActionLab
Жыл бұрын
This is a YBCO superconductor. Also I removed the superconductor from the center and put it farther from the field and still easily boiled the LN2 in a weaker field. It didn't seem like the field was too strong.
@madlad5199
Жыл бұрын
Well, this is a new spam bot.
@volvo09
Жыл бұрын
@@madlad5199 probably generating likes and impressions with less "reports" before the channel is renamed and used for different botting... I've noticed a lot of these lately. even some just saying "whomever sees this I hope you have a wonderful blessed day" and they come up right after a video is posted, so they aren't authentic people.
You do the coolest videos with such amazing constancy!
This is a neat explanation of some of the complexities of superconductivity in a benchtop experiment.
It would be interesting to see some experiments with sympathetic resonance
It will blow up probably lol😂
@Djbuzzchannelyt
Жыл бұрын
Hahahahhahahahhahahah so funny 🤣🤣🤣 😑😑😑😑
@jiddy30
Жыл бұрын
@@Djbuzzchannelyt who spit in your cereal?
@dinithaw
Жыл бұрын
Nah
@cheesebun3461
Жыл бұрын
It didn't lol
@TukeShark
Жыл бұрын
@@jiddy30 he put the milk before probably
This is literally the best example of the video we didn't need but we deserved.
Hi. I have been watching and subbed to your shorts forever. I just found this channel today. I want to tell you I've Keane so much about science just from watching your channel. You make it so fun & interesting. I didn't pay much attention in school and have been left questioning a lot of things happening in the world. You explain a whole lot. Thank you. ❤️
2:09 really disappointed you didn't show more of the magnetic particles inside the coil when you activate it. That was SO freaking COOL!!
Interesting, learned something new about superconductors, I wonder how that would effect a quantum computer's communication. Would you have the same effect with a collapsing field of on, off, on? BTW was the man bunn always there?
interesting topic + to the point delivery + informative = entertaining video.. really good work..
Great experiment. Thank you for doing and sharing it.
Pretty sure its because Super conductors have a limit amount of current /magnetic feild till it just becomes a metal again. Super conductors work because electrons in a metal pair up and make cooper pairs which are fermions and cannot change momentum hence the '0' resistance. When the magnetic field or temperature is too high they sort of go through a quantum phase transformation and revert into transferring current the normal way.
@WouterVerbruggen
Жыл бұрын
Yes, and it depends on both (and temperature as well) at the same time. Even worse, this stuff (ReBCO) is a ceramic in normal state.
@tusharbhudia9421
Жыл бұрын
@@WouterVerbruggen yeah but at super low temperatures its metallic state. I don't see its transformation into a ceramic being the limiting factor over the super conductor transition temperature
Your old hair cut looked more fitting than this new style. Nice videos.
The thing I love most about your channel is you ask the same questions I ask. The difference is, you have an induction heater and a super conductor. .... I only have an induction heater and it doesn't work
Just thought I’d say, I LOVE your channel and what you show us! It’s BRILLIANT👍👍🇬🇧
could there be an effect from vibrations at the same frequency as the current? or would this be neglegible? What I´m thinking is that if current was in one direction, the superconductor would want to float or spin (as they do when they levitate) but since you flip the current, they would sink or rotate the other direction. Would these switches(i.e. vibration) do anything?
@WouterVerbruggen
Жыл бұрын
In a way less, what's getting pushed/vibrated around are the magnetic field "fluxes" inside the superconductor (as mentioned also by James) which costs a lot of energy.
*The superconductor will levitate.* Or it could. That was my instant response to the title question. But that depends on the induction coil being underneath the superconductor.
Wow, did not think it would boil. Thank you for the science!
The new hairdo tho... Love watching the random stuff you get in to out in the garage, always pumped when I see a new upload in my subs
Nice
Huh, that "copper" penny is *mostly* zinc: only the skin is copper. But this is an AC field... Did you do the math how deep the field would go at that frequency and how much of the interaction would be copper vs zinc?
@timk5867
Жыл бұрын
1982 and older pennies are copper
@timk5867
Жыл бұрын
Mostly
@chandrahasreddy1729
Жыл бұрын
German silver is not silver
@CodeKujo
Жыл бұрын
@@timk5867 1982 pennies don't have that obverse side (it would have the Lincoln memorial.) I can't quite make out the date on this one, but I believe it to be at least 2010 because of the design on the back.
Excellent experiment and video!
Answers to questions that I wouldn't even know who to ask. Love this channel.
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@danilosantiago7304
Жыл бұрын
Tra ding systems allow you to limit the factor of emotional influence on decision-making,,
@danilosantiago7304
Жыл бұрын
as well as to give the trade a certain degree of systemic character..
@danilosantiago7304
Жыл бұрын
To the newbies, you should also note that this data is worthless without an existing understanding of data analysis.
@danilosantiago7304
Жыл бұрын
This is very correct and good.
@josejuancamacho7095
Жыл бұрын
@Alina Fischer WASP ⬇️⬇️
Please get a hair cut.
I mean he's a great guy, he's in hospital but still is doing things for us Great Job brother
Great video! Keep on keeping on
Oh my god i was looking for these videos, make more superconductor videos. I like it.
Also I love how in your long videos there is so much more 'Ima press this button an see what happens' going on.
I feel informed. This clarified that superconduction is not so much an intrinsic material property as much as it is a statistical or structural one.
Wonderful experiment. I loved it
What a fantastic video, thank you!
I was also surprised. That's Wild!
This guy is doing actual magic I love this channel
I'm really happy because this great channel exists and I'm one of it's subscribers and you are the best Physicist that I've ever seen even so much beyond the KZread platform, you love your field and we really receive this good sense for creativity 🌹🙏🏻🙏🏻👌🏻👌🏻
Excellent. We do love discovery!
Love this topic you should do lots of videos with conduction and alternating currents.!!
About the steel vs aluminum it's not about the conductivity but rather thanks to the iron magnetic hysteresis, each time the field changes, magnetic domains are following it and it dissipates a lot of energy, more than eddy current with iron. That's why iron/nickel beat all metals in induction, way before copper/silver (good conductors) and tin/lead (bad conductors). Out of this phenomenon, I think the conductivity increases the effet: the voltage is fixed and corresponds to a 1 turn "transformer" secondary. When the conductivity is higher, the current is higher so it makes more heating power. The device source is current limited so you don't see big difference but if it wasn't, copper would beat lead !
@T3sl4
Жыл бұрын
More about resistivity versus what the coil is made of, and a geometry factor. When their resistivities are similar (or, indeed if the coil's is worse than the work's), efficiency is crap and you're doing a whole lot of work for not a lot of heat. You simply get less heat (and other effects like Lorentz force) when it's, say, titanium (coil) on titanium (work), than when it's copper on aluminum, or copper on steel. Or indeed, copper on copper, which maximizes Lorentz force per watt, you could say. (With respect to a given voltage input, say.) Higher resistivity isn't really a problem, to a point -- as long as the workpiece is thick enough to absorb all the applied field (i.e. several skin depths thick). Titanium and graphite for example heat very nicely, despite being fair resistors in comparison to copper or even (pure) iron. Obviously, resistivity can't be too high, else it simply doesn't absorb enough field to matter -- hence why glass, or plastic, or, well, LN2 for that matter, doesn't heat up appreciably (skin depth is almost infinite in them!). And conversely, a thin conductive layer (shallow skin depth) isn't a problem per se -- copper is quite shallow but works very well as a coil. Iron works quite poorly, but its magnetic permeability is making the skin hundreds of times shallower than for an equivalent nonmagnetic material. Superconductors have indeed a microscopic layer, but as long as critical field isn't exceeded in it, that's fine as well. (The geometry factor is basically just to say: you can always make a worse coil. For example, by placing it completely beside the work itself, so they don't couple at all. That's a pretty awful geometry, you'll agree. 😆)
A most excellent video sir!
I'm glad I didn't predict the outcome haha. Very interesting, thanks!
Love the samurai bun. Great vid
Best Channel For Science Experiments ... Action Packed ...
Dude the water ice building up and being deposited in the magnetic field is awesome too
Another great vid😀😀
I kinda wanna see some "electrolyte solution" in the induction heater
Love the giggle bro... me too lol.
Very interesting stuff. 👍
Good science trying just the LN2. LN2 being affected and the superconductor being affected would both be weird results on the surface. I had correctly guessed that the superconductor exhibited more resistance than expected, but the LN2 still had to be ruled out to be sure.
Incredible experiments! Best physics teacher in the world :)
Good one. You should have shown the temperature variance of the supper conductor
I was convinced no heating because no resistance. Eye opening experiment. Thanks for showing us that.
@TheActionLab
Жыл бұрын
I wasn't expecting this result either and had to do some digging on why it would be happening!
@richardgoldsmith7278
Жыл бұрын
@@TheActionLab I love it when science and evidence wins over beliefs and expectations. Knowing that you were also surprised meant a lot to me! 🙂
Please, do more experiments with super conductors
Very interesting!
OO THIS GOING TO BE INTERESTING.
This is super cool.
My soldering iron is induction. There is a small coil in the end of each tip and the core of the tip is different alloys depending on the temp of the tip you select.
And that’s why I love my iSiler induction stove.
Thanks ❤️
So cool !
Brilliant!
Huh, I’ve got it right. Thanks ty my two yrs as an assistant in cryo lab back at uni. Kudos to Kamerlingh Onnes for discovering superconductivity.
Thank you
Great video
This was actually surprising
Very nice
.. we call this an induction stove - and it can be bought in any store for electric supplies .. we have been using that for over 10 years in our kitchen .. (pretty neat, as it has a glas surface)
Ooooh yeah this was a good one
Man you should look into magnetrons and thin film deposition!
WOW not what i expected
Wonderful video
That was my question . I searched in google, but get the answer watching your video
Loving the Cyberpunk Arc with that hairstyle lol
The laughs sound like a mad scientist, so good
@terrafirma9328
Жыл бұрын
As does the hair, ahahahaha🤣
I think if need correct frequency and if in super conductor is a perfect magnet and when place in inductor depend on angle of frequency it would heat too unless it align but if alternating current then it heat too
Love your new haircut
The heating is not caused only by resistive propriety of the material but also because of the magnetic proprieties. Magnetic dipoles in the material oscillates according to the changing magnetic field and this cause heating
Great videos 👍🏽👍🏽👍🏽 Actual applied science 👏
amazing video
I am wondering that the frequency of the current applied into the induction coil depends on the power supply you use. That means, when you turn on and off the switch, there is a step change that changes the frequency profile of the applied current unless the power supply has a mechanism to regulate these spikes and harmonics. In my opinion, these high frequency noises and harmonics may have very low averaged amplitude; but may be enough to penetrate the very thin skin depth of the superconductor. This may not be a big deal unless the experiment requires to find the change in boiling temperature as a function of frequency.