Hello team RECTIFIER! Make sure to watch the next video on the topic: kzbin.info/www/bejne/h2qvpol4m9ypsKM

You can tell he's serious because he doesn't shock himself in this video.

"I couldn't be happier to be wrong and learn something new." -an important moral fiber rare these days.

Very well done and diplomatic ;)

Bad probing is almost always the number one source of error in electronics experiments. Kudos Mehdi

I am surprised that Dr. Lewin did not consider the mutual coupling of the coils with each other in his experiments. In his test moving the probing wires around should change his results. I could not find anything wrong with your analysis. Dr. Lewin seems to verify his hypothesis through the demonstrated experiment which appears to be flawed in how it is setup and yields an incorrect result. First step would be to correct the setup before we even discuss the issue at hand.

"my mom thinks I'm mostly ok." 😂 r e l a t a b l e .

Hi, I'm a theoretical physicist. I don't think Prof. Lewin was completely wrong, but I don't think your reasoning is wrong either. I agree with your calculations, but I think you are not applying Kirchhoff's law as is usually understood from the physicist's point of view. One may argue that Prof. Lewin is also wrong for the same matter when he says that Kirchhoff's law is sometimes wrong. It is never wrong: it's just that it does not apply on certain systems. In the end the problem, as I perceive it, is a semantic and not a physics one. What I am certain, though, is that Lewin proved himself to act rude and arrogant in that comment box. Your objection was completely legit and he had no right to call you an uneducated.

If you don't understand anything, it's fine. He is not explaining it you, he is explaining it to Walter Lewin XD

"My mom thinks I'm mostly ok." It's ok Mehdi. We're all in that boat together. Love you man. Keep up the great work!

And this is why science is based not on authority, but on peer review.

Always express you thaughts. Just because he wrote 15 science books doesn't mean he Is right, or that he Is smarter than you.

Can i just say that watching both this and your follow up video, i think the best lesson to be learned here is how to handle a disagreement like an adult. You found someone who had reached a conclusion that you disagreed with, and were still respectful of their findings and knowledge, while showing the reasoning that lead you to disagree. If more people could handle their disputes like this the world would be a happier place. Best wishes to you.

Interesting to see you challenging Dr Lewin. Science drama is so much better than typical KZbin drama. And this is science drama _on_ KZbin! A new paradigm!

You were totally respectful and very educational with this video. The net result is more people learning about electronics, so I think this is a wonderful video.

Teacher: The test isn't complicated The test:

I am really glad you did this video, not just cause I agree with you. It can be scary to challenge the findings of someone you respect but I think he would respect that challenge because we'll science.

I was working on this same experiment for a Book. And I couldn't find a Simple way of explaining this. You did it in just 15 minutes which is awesome. This is very well done and quite diplomatic I must say.

Maybe he was trying to challenge some unknown genius to step forward and call him out??

I come to this video from time to time hoping I can understand all the concepts explained here a lot better. Out of all Mehdi's videos, this one does even more hard science than Mehdi usually does. That being said, I have learned quite a bit from this great dude, and I do appreciate the fact that he shocks himself a lot just for the laughs and to enhance the learning experience.

You are correct I have experienced different measurement around the loop while performing some practical in my university even my professor were stoked to see that, but I realized later that I had bad probing. Well explained Keep the videos coming and always express it good to see what other people think.

would it be possible for you to start a lecture series about circuit analysis? i believe you are the best teacher i know. theory combined with actual applications/experimentations is the best way to learn. i haven't been bored in any of your videos. you're so good! more voltage times current to you sir!

You just invented Polite Roasting

What I got (reinforced) from this is that even the wire is a circuit component. Since the sense wire folds back on itself and follows about the same path back around, it induces nearly equal but opposite current from the wire that it's adjacent to, cancelling itself out. So you only read the effects of current through the opposite resistor. At least, that's what appears to be happening. He touched on that near the end when he drew in the hidden transformer.

Why do I watch this? I understand nothing.

As a medical student I have no idea what I'm doing here lol

May I suggest an alternative test for probing this circuit: Rather than having the probe wires in the same plane as the resistor loop, instead have the wires perpendicular to the plane of the loop (parallel to the changing magnetic field). Thus, no EMF would be introduced into them until they are sufficiently far away to make the effects negligible.

Your regular, humour-filled videos with shocking situations that make you want to go Ohm, are nice and I love them, but this video was really refreshing. Seeing you explain a confusing topic and simplifying it down so those of us, not too familiar with electronics yet can understand...dude, I need more of this. I think that is a legitimate sign of intelligence.

Dr. Lewin is displaying behavior far too common in the veterened engineering academics in that he clearly believes his knowledge and opinion is higher than anyone else. It is an unfortunate side effect of hubris in this field and I've personally experienced it in many professors. Simply in the way he responded to your comments, insisting that any argument is the result of no education and only his video and lectures can educate you, all the way to that last clip you showed where he reveals that every other author and professor disagree with him and yet they're the ones that are wrong? I recall a professor refusing to allow us to use Thevenin's equivalence when analyzing BJT circuits simply because she didn't like it. Every single online tutorial, university, and textbook insists on its use over 8 KVL equations but she didn't care because her opinion with gospel. Knowledge =/= education and that's incredibly important to keep in mind. You can have all the knowledge in the world but if you don't or can't question that knowledge then you're not well educated.

I like how respectful this video was towards one of the greatest minds in out current time. Its not bad to disagree with someone and politely explain why. This is a great science video with awesome explanation AND a great guide to social communication. Good for you EB!

This is a risk one encounters when delving outside of ones field of expertise. By ignoring the transformer created in his model, Lewin made a mistake that you clearly identify. Well done!

4:48 "I have a coil or solenoid"... Me: This is going to explode. 4:57 "The resistor limit the current to 10-12 Amps"... Me: This is going to explode. 5:30 "Now I'll measure across these two points..." Me: This time for sure.

Great scientists admit when they are wrong and let everybody learn from their mistakes; those other scientists get their ego punctured.

Serious question: how is it possible that such a fundamental question doesn't yet have a solution that the scientific community agrees on? It looks very weird that nobody has encountered, and explained this before with some sort of peer review or it's just Lewin getting it wrong?

never argue with Dr. Walter Lewin.. he will Le Win

Oh, I worked in that field - years ago. The KVL is derived from "E = -grad( phi )" and the corresponding integration theorem. If there is an time varying magnetic field, the true electric field is "E = - grad(phi) - (dA/dt)" . I.e. the KVL holds in the electro-quasistatic approximation assumption, that dA/dt is approximately 0. The KVL is false otherwise.

Uh, if you get different readings, dependent an moving your scope/sense wires around, that might be the hint, that your sense wires and scope position are not just sensing wires, but part of the circuit you created.

Great discoveries are made by those who question the leaders of the field

I will watch this in front of my family, so they will think I'm smart

bro curl(E)=-B_t (where B_t is partial derivative of B with respect to t) is a maxwell eq. it is always valid. while applying kvl u assume that E is grad of some scalar function, if a vector field is grad of a scalar func, then it must be curl free. however we know that curl(E)=-B_t, thus kvl is not always valid, which assume curl(E)=0.

Howwwwlyy Shhieeeett!! When I heard "2 different Voltages across the same 2 points", I questioned my life and all circuits that I ever made ^^ Now that I saw the great explaination it all came together for me. But I do agree with you. It does make a lot on sense when you think about it.

I fully agree that the model is missing an inductor. The ability for a wire to be able to have current induced from a changing magnetic field needs to be modelled in the circuit as an inductance. Just like the lumped element model for transmission lines.

This and the follow-up part 2 video are my two very favorite videos of yours! Your passion is for the science itself...finding the truth...This is the same passion, Faraday, Maxwell, Feynman, and the other greats all shared...You're in good company! Thank you for this series and for the inks to the counter-arguments by Lewin...

From another Electrical Engineer- you got my vote👍

I love this about a person of science. Challenge even the most established idea. Your humble nature shows, and is really appreciated. Good vid, as you demonstrate how the exact positioning of sensory wires makes a massive difference.

Being an accomplished physicist does not preclude him from being wrong.

Why don't you churn out a thesis paper on this?

*I demonstrated at the end of my lecture #16 of my 8.02 E&M course at MIT that two identical voltmeters attached to the same 2 points in a circuit can show very different values.* kzbin.info/www/bejne/pHi0k3Ron9yejas *The reason is that in the case of an induced EMF (Faraday's Law) potential differences are no longer determined; they depend on the path. This also applies to the secondary windings of transformers as the EMF in the closed loop of secondary windings is induced.* kzbin.info/www/bejne/mGjMY6iDrZyaftE *Of course, in cases where Kirchhoff's loop rule (KVL) applies, 2 voltmeters attached to the same 2 points in a circuit will always show the same value.* *My demo was first suggested and published by Romer in December 1982 in the American Journal of Physics.* *This demo has now become a classic; it's done all over the world at many colleges and universities.* *Kirchhoff's original text can be found in the following link, pages 497-514:* books.google.de/books?id=Ig8t8yIz20UC. *Clearly he was fully aware of the prerequisite for his "loop rule". KVL is a special case of Faraday's Law. That's why Faraday's Law is one of Maxwell's equations and KVL is not.* *By teaching students that KVL always works without telling them when it does not work, makes many believe that the closed loop integral of E dot dL is always zero. ElectroBOOM and Dirk Van Meirvenne therefore believe that 2 voltmeters attached to the same 2 points in a circuit must always show the same value which is not true as demonstrated in my lectures.* *They each posted a video on their channel in which they claim to have proof for their wrong ideas which violate Maxwell's equations.* *Apparently they do not know, or do not understand, that in the case of an induced EMF potential differences are no longer determined; they depend on the path.* *MIT students who took my 8.02 course (Electricity and Magnetism) would not make this mistake!* *I therefore believe that to introduce a "modern version" of KVL and then teach students that KVL always holds is not advisable as you may set them up for making the same embarrassing mistake that both Dirk Van Meirvenne and ElectroBOOM made.*

Dear Mehdi Mercury, I am (was) an electrical freshmen. After watching all your videos over the weekend, I decided to switch to Business & Management because I can no longer solder or plug in something to the outlet without imagining sparks.

I find it a little disconcerting that a professor at a leading university who is well accomplished in his field proposes a radical change to a commonly accepted theory and then doesnt want to argue it because he is tired of arguing. Extraordinary claims require extraordinary evidence. It is a basic tennant of science imo. You dont get to make a great claim and then refuse to have the conversation and thereby win by default.

"My mom thinks I'm mostly OK" Words to live by brother.

Hmm...that is the basiscs of everthing: the ppotential difference as Voltage is only valid in a electrostatics, where the electric field is concervative. I think, this is tought in the very first lessons of every electrodynamic lecture.

I had been wondering about Dr. Lewin´s experiment since the first time I saw it. I watched it several times and had come to a similar conclusion. Since this is an air core transformer, any nearby wire is part of that transformer. Magnetic fields can have very complicated effects. Basically I´m glad you adressed this.

Medhi, I love your channel. I'm sorry to say both of you are arguing past each other... I'm a physicist who plays an EE at work so let me see if I can offer my 2 cents... The secondary of the transformer you refer to is an effective lumped element representation of the mutual inductance between the solenoid and the loop with the resistors. There is a secondary for the sense wire loop as well. However, the lumped element approach isn't general. The mutual inductance has to be calculated for a particular geometry, not a circuit, using you guessed it... Faraday's law. So you can only model the secondary if you have already solved the emf for the system. Lumped element then can be generalized for the flux profile so you can change the waveform, which makes it a powerful approach for circuit analysis, and makes the EE masters happy because they can just treat it like a circuit element and do normal AC analysis. See the appendix of Clayton Paul's book Intro to EMC for a fully worked example of this exact treatment. Now give me a damn oscope please.

I remember having a similar conversation with one of my instructors as well. He simply said, high tolerance applications, use Kirchhoff's Law. For low tolerance applications, use Faraday's Law. I doubt I would have caught this. This clears up a lot for me.

Kvl is a simplified form of Maxwell's equation obtained by lumped matter discipline in which we assumed dphi/dt = 0 I.e zero change in flux.

8:53 Dr. Lewin ended up not being a nice guy

"If you do not agree you need to be educated...This is very very basic physics and I never argue with people who think they know but who do not... The stunning demo at the end of my lecture..." His attitude doesn't mean he's wrong about this particular thing, but it does mean he's not worth listening to.

This took some head scratching but I think I see the disagreement here. I usually explain KVL by analogy to elevation: if you walk in any closed loop here on planet Earth, you must necessarily have ascended exactly as much as you descended, because you end up at the same elevation. Dr. Lewin, I'm sure, would tell me that elevation is an incomplete analogy for voltage. If there's wind, for example, it'll be harder to walk into the wind than have the wind at your back. In this analogy, a changing magnetic field in a loop would be like trying to walk around a small cyclone: go with the cyclone's rotation and the wind is at your back, go against the cyclone's rotation and the wind is in your face. In that situation, "voltage" becomes harder to define because which path one takes between point A and B affects the work required to get from point A to B. Mehdi is arguing that the "wind" from the "cyclone" can be incorporated into the model, and so the "voltage difference between two points" becomes well-defined once more depending on where the cyclone's wind is worked into the circuit. In a sense they're both right and folks should really just go with whichever model helps them accomplish whatever they're trying to do. (But if you have two pieces of equipment measuring the same thing and they disagree, something's probably up and you need to recheck your experiment.)

One of my subscribers just turned me onto your videos. Absolutely magnificent stuff your brilliant! Going through most of your videos now it's going to take me awhile, but I'm having a blast. Thanks for sharing

It was an excellent demonstration of the importance of considering all the details in a scientific experiment. In the demonstration, the hypothesis is raised that the consecrated Kirchhoff's Law could be nonsense, depending on the side where the instrument that measures the same induced voltage is positioned - an obviously absurd hypothesis. If the measuring instrument (oscilloscope) is to the right or left of the same circuit, the voltage reading should be the same - but in the demonstration it did not occur. Thus, the hypothesis that the said Law would be flawed was proven. The layman certainly went unnoticed that in both measurements, right and left, the circuit was not the same. The circuit, in fact, is not only what the demonstrator draws, but also the wires, cables and the internal impedance of the oscilloscope should be considered. As it is electromagnetic induction, any opening between wires will have voltage induction by the variation of the magnetic flux that surrounds them. The measuring circuit, to be the same with the instrument on the right and left, should be what was drawn by the demonstrator at 12:04. Soon after, he shows in practice that he did not follow what he drew; leaving again a new half turn wire near to the experimental loop over the magnetic field generator. It was an excellent joke of illusion. Thus, the hypothesis of failure of Kirchhoff's Law can not be confirmed.

The Kirchoffs Voltage Law used by Dr. Lewin and Electroboom are different. I think Dr. Lewin uses line_integral(E.dl)=0 as KVL, which definitely is incomplete, as this only says that the sum of voltages around a loop caused only by an external electric field is zero. According to this the voltage across an inductor is zero, as it is produced by a magnetic field and this is where Faraday's law comes into picture. But the KVL used by Electroboom is "the sum of voltages around a loop (caused both by magnetic and electric fields) is zero". This includes the induced voltage across the inductor (L*di/dt, which actually is a consequence of Faraday's or Lenz's law). So now it all comes down to which of the above versions was originally proposed by Kirchoff in his original paper.

1:20 everyone. Imagine this world if just more people had Mehdi's scientific and philosophical humbleness

The first serious video in this channel 😂 A lot of love to Elctro Boooom

As someone uneducated in the field, I came to the same conclusion before you finished talking. I would love to learn why you would be wrong as I currently don't see it. Your arguments make perfect sense to me. The probe wires are part of this experiment when it is setup like this.

can you show how to change a lightbulb? I already tried 2 times and almost killed myself with resistance and capacity

From Maxwells equations, the electric field E = minus grad V minus derivative of magnetic vector potential A. Obviously, mathematically, the sum of grad V around a loop is zero (~V2-V1+V1-V2). The question is, does the voltmeter measure grad V or E or something else in portions where A matters. It clearly doesn’t measure grad V, because the result depends on how you position its leads. The magnetic field affects the leads of the voltmeter and induces an additional E, thus current, inside them, which depends on how you position its leads in this magnetic field. The additional E is given by the rate of change of the total magnetic flux (magnetic field times area) through the closed loop formed by the meter leads connected to some circuit element. So, even if your leads follow the wires of the circuit, when you flip their position perfectly, grad V changes sign, while the additional E doesn’t flip sign. So, to eliminate it, the loop of your meter leads have to be parallel to the magnetic field (zero flux).

It's very brave of you to challenge someone like that. Keep it up

Mehdi is soo near to 2M...

The way you explain it, it seems so obvious, but I have a Master's in Civil Engineering, so what do I know? I studied water.

Kirchoff's Voltage Law always works under one of two possible conditions. The first condition is that you wait long enough for the system that you are measuring voltage from to stabilize, or alternatively that it is a lumped parameter system (this would assume that the wires connecting components are negligible). The concepts explaining why this is so are summarized under the topic of transmission lines. With the help of the telegrapher equations, derived from Maxwell's equations considering a source-free space and the transmission lines that carry the signal, one can analyse the response of a signal in a circuit looking at it as a wave that travels at a fraction of the speed of light. This fast moving signal does not behave according to Kirchoff's voltage law until it has reflected and super-positioned onto itself sufficiently many times to stabilize to the expected Kirchoff's voltage. In other words, Kirchoff's voltage law is not wrong, it's only wrong to apply it to non-stabilized circuits or with non-zero length lines (which would not be a lumped parameter model) between components. With regards to the measuring of two different voltages between the same two points I completely agree with ElectroBoom. Not even at the fast speeds of waves traveling on transmission lines, given no reflections, will you be able to measure two different voltages at the same points. This has less to do with KVL and more to do with simple equa-potential of a point. The potential difference between two points in a medium, from Maxwell's equations, can be defined as the integral of the Electric field between the two points along some chosen simple path. Now, in the case where the B-field is changing, you can simply treat the total E-field as the sum of the regular E-field and the induced E-field (which is the partial time derivative of the magnetic vector potential) and voila, you have a net E-field from which a specific potential difference can be calculated. Having one equation and one unknown implies, from simple mathematics, that it can definitely be solved.

Well, I am surprised that Dr Lewin made this nonsense statement. Ofcourse Kurshoff laws hold. At least in this case, the problem is simply linked to the probing. The problem was clear from the beginning. And coming from a good experimental fellow like him, I am really disapointed. I spent my entire PHD developing a magnetic localisation system and if i have learned one thing during those years of experimental setups is to check and double check your wiring. Every bit of wire can act as an inductor and depending on which direction you wind it compared to the source of the varying magnetic field, it acts differently. I remmember running to a similar problem when building my first coils. A little untwisted wire absorbs a suplement of signal that completely falsifies the magnetic localisation by few centimeters (for a body parts localisation system, this is a big deal). Back then, I didn't even think of blaming Kirchhoff. I just started by checking my wiring and understood the problem in no time. Physics don't lie. Some laws are so established today that one must start by checking the experiment setup before even if it is Dr Lewin. But who doesn't make mistakes?? It happens to the best of us. I am a little disapointed though. Where are the sparks?!!!!!!!! Not even a little shock?!!! Is this electroboom or the school of electronics?

9:56 "Why did we read 0V across the sense lines?" Because the path is different. At 9:26, your measurement loop encircles the flux, and the scope’s resistance allows a a path for the current to flow which arises from the induced emf from that flux. At 9:40, you’ve arranged your measurement loop such that it doesn’t encircle any flux, so there is no induced emf in that loop. In both cases, your scope is responding to induced current caused by the flux change thrugh the loop it forms with the probes and the wire arc. In the second case, there is little to no flux passing through the measurement loop as it doesn't encircle the solenoid -> no induced current -> no measured voltage. at 9:47 you find that you can get different results depending on how much flux you enclose. I can draw a picture if this isn't clear. 10:03 "If the voltage here is +V" But... It isn't. There isn't a localized potential difference there. Your previous measurement of +V depended on the path. Then you changed the path. This is covered in Belcher’s notes in the second video. But my intuition with this one is still shaky... Faraday’s law specifies that in the circle strictly around the loop, not including where the probe wires diverge, there is still am emf of 1V. In this particular circle, the impedance is high so there would be no resultant current across the gap, but how should we think of or visualize this EMF? imagebin.ca/v/4Qi4j6Awhq4w

A schooling in Metrology101. Step1: Check stray inductance, capacitance & noise. Step2: Marry me and give me scope.

I am a law student who desperately wanted to study physics. I've searched for law stuffs, and KZbin suggested me this. Thanks to KZbin for realising my heartaches.

The E field produced by a changing magnetic field is rotational and therefore can't have a defined potential and thus its values between two points depend on the path along which you make the measurements, as long as you believe in Maxwell's equations and vector calculus you must accept this even if you're able to come up with a specific example where they happen to be the same.

I completely agree, im a janitor and i got shocked once so i know my stuff.

Every wire in a practical circuit may be considered an ideal resistor and inductor, no matter how short it is or how low resistance it may be.

I agree. I'm an OLD electronic tech/engineer and have seen this sort of thing come up as a problem in a industrial installation.

A better demonstration would be to magnetically shield the sense wires so that the measurements still read the same on either side of the circuit. That takes the variable out of the equation.

I watched that class a couple of years ago and I found it very weird. I assumed he was talking about some advanced definitions and that the model of the "imaginary" inductor as a voltage source was a way to make KVL work out for induction machines. Now I feel so much satisfied with your reasoning ♥. Also I like to imagine the straight wire as a collection of tiny inductors in series, even the resistor itself acting as one, so that is NOT ok to assume 0 voltage drop just because the resistance negligible

When a distinguished but elderly scientist states that something is possible, he is almost certainly right. When he states that something is impossible, he is very probably wrong... - Arthur C. Clarke

This video illustrates why I subscribe to your channel. While the majority of your videos have an important entertainment value, they're based on scientific principles. I appreciate the level of critical thinking you are able to apply to the many scientific laws of electricity. Thank you for the work you put into your videos.

It calls for a epic rap battles of history Martin lewis versus Electroboom

Richard Feynman would be proud of you for disagreeing with a master

New to the channel (probably one of the best KZbin channels yet). Love the video! and as an EE student, this totally makes sense, and I couldn't agree more. Keep them coming!

I don't want to take sides but Dr. Lewin's reasoning is sound. KVL as we know it from (lumped) circuit theory can be derived from Maxwell's equations as a particular instance. If the magnetic flux enclosed by the circuit (contour for the path integral) is negligible then the voltage produced by it is negligible and we get the known KVL for voltage. This is much better explained in Harrington's "Time harmonic elmag fileds" with a nice summary in Table 1-1.

This is shocking! ;) I love Dr. Lewin. He is a great instructor and top of his game in physics. As a scientist, I find I am wrong daily. It is the nature of science. If we were never wrong, we would never have to do experiments, we would just write up our hypothesis--like string theorists---ouch..... Dr. Lewin, as brilliant as he is, needs a little more humble pie in his life. Assume a spherical humble pie! ;)

I think one have to do more practicals than reading theories. But sadly our school curriculums have no time for practicals, so only 15% learning. ElectroBoom sir, you're a great master. Thanks for this.

I think it’s really a matter of technicality, if you are willing to look at the circuit as two separate components, a Transformer / voltage potential source, and a circuit not subject to changing magnetic flux, then you can use KVL and get an appropriate result, because you are factoring in the contribution due to Faraday’s law. However if you are to analyze the circuit in its entirety you must use Faradays law as using only KVL gives no indication of the potential difference between any points in the circuit without a source. I’ve watched Professor Lewis’s entire 8.02x lecture series, and really appreciate his contribution to education in physics. But I think this fight is rather pointless, we all agree on the results, we just don’t agree on the classification of our methods of analysis. Engineers like to think about KVL as just adding the potentials through a loop, and if the result isn’t correct it’s because you’ve neglected a term. Physicists such as Dr. Lewin like to think of KVL as a special case of Faraday’s law, simply because it doesn’t hold in every case unless you factor in the contributions from Faraday’s law, which happen to be zero most of the time.

Hello sir, I’m not sure if I’ve understood your video but in my opinion what professor lewin is talking about is maxwell’s equations. One of maxwell’s equation says that in presence of changing magnetic fields, electric fields are no more conservative therefore the work you need to do to get from one point to another does depend on the path you take and potential difference is just the work you have to do divided by the charge you’re holding

Strictly speaking you are not correct. If you have a vector field with zero curl, you can always write that vector field as gradient of an scalar field. This is the abstract form of conservation of energy. In electromagnetism, if curl of E is zero, we can write E as gradients of a scalar field V. That is the formal definition of voltage. When you have time varying electromagnetic fields, curl of E is not zero and thus voltage in the sense of Kirchhoff’s law is not well defined. Taking the integral of E.dl is going to be path dependent which is why you get different numbers on different path. You can break the distributed circuit into many pieces and talk about small voltage drops on the sense wire line, but that would be the same as taking the integral on different paths. You can do that because your volt meter is measuring lumped and distributed volt meter doesn’t exist

Physicist Vs Engineer.

"My mom thinks I'm mostly okay" I think you're okay too

Kirchhoff’ law is for static fields. Given this fact the argument is doomed as we already know we are in trouble. The voltage between 2 points does not make any physical sense if you have a time varying field. You can only measure voltage acting around a complete loop. So measurements depend on the path of the wires connecting the 2 points. Replacing the distributed induced e.m.f with a transformer is not valid. In reality there is an induced electric field acting on all the wire so replacing with a transformer does not model the physics correctly. Choosing a straight path between the points does not help anything. In short there are somethings which can not be modelled with a discrete circuit and this is one. To understand this properly you need to think in terms of fields. But as always very entertaining presentation.

Where we you when i was studying? That's some beautiful explanation.

WoW ! - I feel like I'm watching two gods fighting each other on mount Olympus and I have a BSEE degree.....

I sent this to some of my science teachers, im curious of what they are gonna say about it. You have all my support👊

11:00 KVL states that, i*R1+i*R2=0 (i !=0) => R1=-R2, given that a resistor is a "passive lumped element" and this equation couses a "passive element rule violation" since one of the resistances is below zero. So in that case KVL does not hold and the induced voltage should be calculated by the "integral E dl" which means that there exist electric field change (voltage drop) through the loop wire which has 0 resistance we assume generally and that is a contradiction.

I am probably more wronger than both Mehdi and Lewin (I only have bachelor in applied physics), but here is my input: I would like to point out that it is not something groundbreaking. Basically Kirchhoffs law is a simplified case of Maxwell's laws of electrodynamics and/or electronic version of conservation of energy. Now what Lewin is doing here is saying "in case of external magnetic field, this law does not hold and needs an extended version", so he provides a Faraday's law that assumes, that system is not isolated and energy comes from a dynamic external magnetic field. Mehdi has another interpretation - he says "dynamic external magnetic field is a part of system and we can model it as a transformer". This is not unusual - different approaches - if correct (in this case - they all follow Maxwell's laws of electrodynamics) - they should yield the same results. Now for the correctness part - I would say Mehdi here is more correct (something that might come from experience) - physicists have a very hard time modeling their measurement instruments as a part of the system - at least in other way than providing possible errors - so I can easily see Lewin ignore the fact that wires leading to voltage meter form some kind of loop and are affected by external magnetic field. But both approaches should yield same results because they all are correct with Maxwell and we ignore this pile of crap that QED is.