Love it. I get popcorn for Veritasium's and Electroboom's responses.

Veritasium blew my mind, and you are piecing it back together again, thank you.

Electrons can totally leave the wire, if it's hot enough :P

d is correct if the switch is near the light bulb because the wires are already charged + and- and then there should be a slight drop and go up again

Nothing too important, but you used V as the symbol in Ohms law, however V is the unit and U is actually the equation symbol for voltage, just like I is for Amps and R for Ohms, Love your videos, thanks for educating us all

Eĺectroboom's answer was very good too , electricians/electronicians i guess

Background in physics and materials science (emphasis on semiconductors 😁) All my electronics projects are very hobby-level, but hey, now I own a scope, so maybe I’ll finish that Theremin I tried to build in undergrad and finally satisfy my curiosity for oscillators xD

Agreed, thank you

I also agree! Great video, great experiment! Warm greetings from germany :)

@@AlphaPhoenixChannel that background is what makes your video on this so much better than everyone else's. This is a situation where the nanoscale mechanics DO matter, and those who don't study semiconductor physics are taught that they almost never matter. Well, that and they aren't ever really taught at all, because the math involved in semiconductor physics is complicated! (and fun; the class I took on them was my favorite in all of my time in college :))

looool 😅

Everything is a lightbulb with enough current at short enough timeframes.

X'D

Cigarette lighter

Everything's a lightbulb if you're brave enough

agreed. i want to see the same exact setup but with a Faraday cage to block the EM field between the battery half and the light bulb half.

The idea that excites me the most is the idea that he’s just doing what he loves, he has a passion for creating content and he is VERY good at it, imagine if he released some sort of online class.

Glad you liked it! It was such a frustrating question I HAD to set it up. I ordered the scope less than 6 hours after watching Derek’s video…

@@AlphaPhoenixChannel - You know, the largest discoveries usually stems from, "hmh, that's odd...". This question/example had me frustrated as well, but I don't have the equipment to do what you did. Really appreciate both you taking time, and your teaching skills! And to think I thought you were crazy when you made your laser video... Thank you very much, Brian!

Yeah, this guy would make a phenomenal teacher. 🥳

Yup, same here.

Think this is more of a new to him experiment than actual new science. Which is awesome and not trying to be a Karen, just felt a little misled. Keep on testin bro

@@randycorp5333 Where do you get "new science" from?

I find that with a lot of Veritasium's videos. I can't tell if he deliberately overcomplicates things on purpose in order to create controversy and get views, or if I'm just not educated enough in physics to keep up. With this video in particular I came away very skeptical as well as confused.

@@OutdoorsWithChad Vertiasium is primarily a content creator, not an educator. I stopped watching his videos because he would prioritise clickbait and spectacle over actual education on concepts. Sometimes he wouldn't even his due diligence and straight up just promote incorrect claims without correction. His video on post-truth is a great example of how without demonstration, he struggles to convey a concept clearly, if at all.

Ah yes all of these words make sense to me. lol. I’m loving that Derek sparked so much enthusiasm for science with that video, even if proved right or wrong, this thought experiment is wonderful to uncover through all of you.

Mehdi, you forgot to mention the step when you get shocked :P

Are you going to make a video on this?

So interested to read this. It also seemed to me that the capacitative coupling was high for two wires a meter apart. The probe capacitance would explain it. Cool.

@@hippopotamus86 He did, a week ago

Have u seen electroboom's video on this topic ,concise and straight to the point from engineering perspective.

cringe... passive aggressive cringe

In this era of fake news we don't trust people and theories, we need proof

ActionLab lets gooo

@@GAMEOVER-yy6zj yeah and he goes into more detail too, it was a great video

Nice!

I thought about trying to calculate the necessary size/spacing of the wires to impedance match a typical lightbulb, but I’m not convinced that the standard transmission line model applies here, because all of those calculations are assuming you’re pumping the same signal into both wires at once. There’s very particular capacitance and lack of cross inductance that falls out of that. It’s a fun thing to think about. I played with load resistances a bit but I was also fiddling with the source impedance and generally trying to keep everything high enough that the tens of ohms in the wire itself didn’t matter, and get to dc as soon as possible - you can see in these traces it took vaguely 2-3 light speed delays, and some of that was due to only switching on one side of the battery. If you can get a better match itd be pretty cool! Edit: I’d also add that making the spacing a full meter made the effect even weaker, although that didn’t make it into pt.1, so getting it to match is an uphill battle.

This is what you should have done in the first place. I like your videos, but that one was really bad. Instead of making physics accessible to everyone, you made a non existent light bulb, that makes physics look like black magic. With magical light bulb, physics seems like magic. Nothing further from truth. Physics are simple and very understandable when properly explained, like in this video. A real bulb will never light (or if it does, it would explode after 1 us). Also units were wrong in your video. I hope you do a video explaining it correctly.

IMHO absolutely yes. The standard transmission line model can be used; you have _two_ transmission lines, one going to the left and one going to the right. Say the impedance of the particular geometry (wire diameter, wire spacing) is 800 ohms. Now your 'bulb' (resistor) is connected to the battery and the switch by two 800 ohm impedances. Make the load 1600 ohms, and half the battery voltage will appear across the load. Note: the 'standard' transmission line model _ignores_ the speed of light across the gap, and only considers it along the length of the line. So by the standard model the voltage would rise instantly across the load. But of course we know that there is a delay across the width of the line and the rise time would not be instant. IMHO the standard transmission line model is sufficient to describe things at time scales where the the signal will have traveled perhaps 10x the width of the line. Setting up a signal source and scope that can see the shape of the initial rise as well as the step when the reflection comes back from the ends would require a bit more in the way of resources, because now you need a scope with GHz bandwidth. And Derek, I really want to thank you for putting the original video out there. It made me think about something that I already knew in different ways, and deepened my understanding. I've also had lots of fun discussing the various response videos. -Jon

Hi Derek, To get higher voltage, impedance matching would at least bring your voltage up to 6V. Of course even smaller load resistance would raise the voltage even more. But then the large resistance might make it like a very non-realistic lamp. You could bring the wires much closer to increase the capacitance between the lines and so a smaller line impedance that would increase the load voltage, as a proof of concept. But at 1 meter gap, well, I'm afraid there may not be enough juice ...

Lol exactly my thoughts. Lucky us benefiting from these science debates that would’ve otherwise been out of our sights if it weren’t for KZbin

*flat earthers enter the chat* ugh

It has gone downhill for many years.

Haha wait till you get to gigahertz radio equipment (or anything over 100Mhz)... Now imagine trying to model these way back in the early days of radios.

Wholeheartedly agree with Goodgu - everyone else seems to have completely missed the point. Even the talk of inductance/capacitance seems to miss the point really, but it is good to see the actual effect quantified after so many people relied on it for their whole explanation. The question is ENTIRELY about the whether the energy is carried by the Poynting field, or by the moving electrons.

totally agree. The oscilloscope cleared it up so much. Especially with the cut wire.

I believe that this plus electroboom's video are the perfect combo

@@paulwright8695 We already know there are charge effects that will occur over distance and the strength of those effects are inversely proportional to the distance from the charge, in this case the electron. You can mathematically describe what is happening but it doesn't change the reality of how it works. The energy is both In the wire and Outside of the wire. The fact that the electrons are strongly coupled to the conductor and move inside of the conductor (sometime closer to the surface depending on the nature of the current) means that the majority of the energy carried must be proximal to the electron. That is why the conductor's are carrying most of the power, and that is why the Original Video that Veritasium presented is highly misleading because it suggests that (Paraphrase) "it's all about what's happening outside of the wire, not what's happening inside". And that is simply incorrect. I do wish Veritasium had posted his own video walking back his claims when it became quite evident (even by his own words) that the light would not turn "ON" but instead was only dimly lit. (I actually doubt a real light would actually be on by any reasonable stretch of the definition, but I would accept 80% of nominal as on or even many other versions of on. But a slight glow... no) I really appreciate this actual demonstration. Again, you can't run this kind of stuff on a simulator and expect real results until they have been verified by experiment. And I am very very disappointed that Veritasium didn't actually do a REAL Demonstration to prove it when he posted his video or at least say his next video would show proof.

@@paulwright8695 The last sentence doesn't make sense, it are moving electrons that cause the poynting field. Arguing about which one is the actual cause of energy is useless, because they always come together. (And that is why Veritasiums video is just bad science communication)

You're forgetting the using a tailwind to move faster than the tailwind debate :D

Totally! It feels like a very constructive and entertaining application of Cunningham's Law. I love it! It feels like the great debates you hear about between scientific giants in history and it's very exciting!

I feel like, more than anything else, it has shown people that disagreeing is fine. And saying that you disagree with someone is not a personal attack. The world seems to have forgotten that over the past few years.

So is it as fast as light or not? Cause I don't have time to watch 25 minutes for a yes or no answer.

@@johndawd4616 the answer is yesn't

I really like the electroBOOM one too because he made the excellent point that if "any current" counts as the lightbulb being "on", then the lightbulb would always be on because there's lots of little causes of current constantly in that kind of setup For example, it seems like the wind caused static electricity which caused all kinds of noise in the measurements? And I assume even if everything was isolated very carefully, we'd still be able to see a non-zero current with sensitive enough equipment? I'd be really interested to know how much variation there was in the "background" level of current in this experiment.

Yeah there were pulses of nonzero current all the time but it wasn’t continuous so if I triggered the scope a few times I could see a clean trace. In retrospect a 10k resistor in parallel with the battery probably would have helped that quite a bit (at least for the trigger probe on the yellow trace)

@@AlphaPhoenixChannel Really interesting. So in the original thought experiment where "non zero" counts as "on", the lightbulb would actually be turning "on" randomly (or even just be "on" continuously) even with the switch open all the time.

@@AlphaPhoenixChannel The trace may look clean but as I'm sure you're aware if you had a device sensitive enough it's generally impossible to get absolutely zero current transfer in the real world with, you know, stuff moving around, even cars driving or radio waves floating about (such as how a crystal set radio doesn't need a battery). So by Derek's definition the light globe would always be on no matter the setup in the real world... it's almost as if it was unnecessarily contrived to create a clickbaity video... who'd have thunk it... 😉

@@TristanCunhasprofile It would be on continuously in the real world even if there was no circuit, if it could truly detect non-zero current, just from very slightly charged things about in the near environment. Rubbed your hair and got some static electricity? That's a charge! That'll exert some movement of charge across the lightbulb just by standing near it. Etc etc etc. That's also why Derek's setup is rather contrived, so much so he shot himself in the foot with it.

Come back in 3 days and you remember barley anything ... but you still feel the „smart“-feeling you’re feeling now. The problem is that the actual knowledge which this feeling was founded on is probably long gone or at least badly fragmented. That’s at least what I observe with myself when I watch “educational” KZbin videos. Yeh they might be informational and highly insightful, but nowhere near comparable with real schooling. I sense that might be part of the reason why today everybody on the internet feels entitled to vent their opinions about subjects they clearly lack real competence on. What are your thoughts on this? Do you observe similar things to happen?

@@petergoestohollywood382 You are the definition of a Jew lol

Me too! He's done a fantastic job here!

@@thalanoth What do jews have to do with any of this?

​@@petergoestohollywood382 , it depends on the extent to which you are already familiar with subject matter. It's all about how willing you are to fill in the gaps in your knowledge to make what's being shown to you simple. Direct guided teaching is a must in primary education, and mostly necessary in secondary education, but even very young children can teach themselves a lot about things they are genuinely interested in, provided they have good resources, with both information _and_ guidance. This has certainly been true for me for almost all of my life. Of course I can't speak for others, but I feel that were others may not have had similar experiences, it was because they were not encourage to do so, did not have strong interest in any particular subject area, or just did not have access to good resources. The biggest part of _schooling_ is teaching people how to study independently, not simply spoon-feeding them information. As someone with an understanding of physics at a suitable level, the descriptions/explanations given in this video are basically second nature/obvious to me. If you were a 14-year-old student of physics in high school, you'd likely just be starting to get an understanding of things such as the electric field, electric potentials, circuitry etc. at a suitable level to understand what's being discussed here. Having said that, I feel that a young child could quite easily understand what's being said here, if only it's presented in the right way. I have gone back to content that I consumed years ago and which was originally insightful, enlightening, or even just piqued my interest or made me aware of a particular facet of a particular subject, but whose content I perhaps didn't quite fully understand at the time; and now, having since studied that subject facet in greater detail, that content is utterly obvious. To _learn_ is to overcome preconceived notions, and to understand and apply new concepts. Such content may afford you a certain level of understanding (at least if you can overcome any hurdles regarding overwriting preconceived notions), but without also learning how to apply the concepts discussed, the knowledge simply won't stick around for long. That's just how short- and long-term memory work. For example, when I as 7 or 8 years old, my teacher showed me and some other students how to solve simultaneous equations (a system of two linear equations). All of us understood the logic of each step as it was shown to us, but none of us could reproduce the method or answer similar questions unguided, simply because we were not that familiar with the method; but also because we weren't completely used to thinking of things algebraically/abstractly, so re-deriving the steps was not intuitive/obvious. Of course, 4-6 years later, we would all be solving such questions routinely without difficulty, having been exposed to and come to understand algebra in that time.

These guys should really bring an Electronics Engr on board. Because we understand the imperfections of circuits. I saw one video where the physicist was totally flummoxed by switch bounce. I saw one video where the physicist totally misused the terms voltage and current.

@@QualityRecord Misusing the terms voltage and current is something a backyard mechanic does, not a physicist. Either the physicist forgot the basics, or the physicist was not a physicist. As far as an electrical engineer, I was an EE major in college and we learned how to use those terms the first day. What annoys me as much or worse are those who don't distinguish AC from DC. To mess that up you are not at all qualified to be discussing anything about even the most basic electronics. It's like if someone is discussing their sound system with me and I ask the ohm rating of the speaker and they tell me "300 watts". I know at that point I best say no more.

How? The current running through a wire does not move with the speed of light... Experiments like in this video like to claim as much but basically it has only roughly the speed of light. In reality it is probably around 90% of it or even less. Or do you now the speed of the current for that particular cable?

To further explain it: The coax cable has characteristic mu and epsilon constants, which, in turn, define the propagation velocity of the electromagnetic wave. When the other end of the cable is ended with an impedance load matching the cable's impedance (50 or 75 ohms) there is no reflecting wave. Still, when the cable is broken or shortcut, then you get a reflected wave delayed by the time it takes to travel from the source to the breaking point and back. web.physics.ucsb.edu/~lecturedemonstrations/Composer/Pages/76.18.html.

​@@KM-bu5ywthe current doesn't flow at the speed of light, but the electric field that produces the current does. Therefore, you can do this same experiment, measure the time difference between switch on and voltage bounce, divide by c and you got it

@@camsaffari I thought the illustration of the electrons in the wire was very helpful in explaining why the wire behaves like a capacitor. I have never studied electrical engineering, so electroBOOM's video was a little over my head. I thought this video explained many concepts very well. I'm just happy there's lots of great content: we can get many different takes on Derek's thought experiment and that I've learned more about how electricity works.

Right on. I guess "debunking" gets more clickthroughs than "slight adjustment". It's feels especially odd coming from Derek considering his recent video about honest video titles vs. clickbait titles. (kzbin.info/www/bejne/iWPbeY2GfZqGpMk)

@@runamucker He's just applying that, as well as making ads, to make money. There is nothing odd about it. The only odd thing is sacrificing the education aspect spreading misinformation to get the money goal, which is revolting.

I think @Veritasium is addressing the general public who haven't studied science or engineering a lot. For the trained and self-taught amongst us, that video is kind of a revision of topics from electromagnetic fields, transmission lines etc.

Exactly right, no one cares that the wires are 1m apart, we want a giant circle long enough to see the delay of electricity travel. These eggheads are overthinking the question.

No thats the normal field. If you zoom in far enough you can see tiny Daft Punk concerts on the wires. That's the electric field

And if you’ve ever seen a romance movie where two people run down a field to hug and kiss that’s a magnetic field

pasture for electric sheep?

If you want to be technical, the electric field is everywhere, so you're never really wrong.

I think you'll find he is out standing in his field

You, sir, were a huge inspiration for me while I was going to school for EE many years ago. Thanks for that!

I am also not rich enough to spend on experiments which doesnt give me bread

@@deva8496 Rich? Lul.

Yo! I watched a BUNCH of your videos while setting this up, really hoping I wasn’t making some horrible mistake since I hadn’t used a scope in years… thanks!

Not many of us have a 1/2 km farm to play with.

Nothing crazy, a luma/brightness keyer can separate darker object from lighter ones (such as fingers in front on white paper) reasonably well to work in this scenario, it's a nice touch.

@@lgab Yes BUT he keyed the graphics OVER the real set up. Then his hand passed OVER the graphic.

Woah, I didn't even notice it, that's how natural he made it look. Good observation.

@@blaster-zy7xx This is called a difference key and works (only with a static camera position) by keying what's different from a reference frame from the same camera; works very well when you have a background as different from the keyed object as the white from his hand there (and the lighting is constant). And it does help the illustration a lot indeed.

It’s a combination of two moving sets of powerwindows for my hands and sleeves, each window contains a chroma key (skin color and black jacket color). A difference matte didn’t work because the table moved when I leaned on it, plus the wires laying on the table occasionally looked like skin or like jacket and had to be manually removed

Thank you for your clarity in resolution. I appreciate this.

Same! I didnt really understand Veritasium, and Electroboom helped a lot, but that exact moment was like 🤯

Same here! Awesome part!

These “pockets of charge” are also a gross oversimplification.

@@noop9k isn't everything?

Same with me. I've watched a few different videos addressing it, and this is the first time it all made sense.

I left the highschool thinking that induced current is basically black magic. We were told that induced current has to exist because of conservation of mangetic flux and that transformators work on the principle of conservation of energy, I was able to solve the problems of this type but I always viewed it induced current as hocus pocus.

@@smrtfasizmu6161 To clarify - what I've described here isn't induction. Induction uses magnetic fields, not electric fields, and is a fair bit more complicated to explain without math... I personally hate explanations that lean on math so if I generally wait until I think of a good analogy before talking about something...

If they are struggling to understand capacitance then I am sorry to say, you are not teaching it right. Let's take the example of a parallel plate capacitor with an air dielectric. It's incredibly easy to explain and the formula describing the capacitance is also incredibly easy and logical. Moving then towards capacitor with a non air dielectric is then one simple step further on. You could even talk about the effective series resistance, though when I was at school level physics they didn't cover that Things become a little bit harder with inductors and magnetic fields, but even the basic equation, Faraday's law is simple enough, and easily demonstrated.

DC electronics theory is hard enough for the novice student. Throwing in capacitance, inductance, and AC electronics principles will seem like black magic until it is learned.

Hear, hear! We're not Greek philosophers, we don't just construct arguments... we _test_ things.

Shhhhhh...we're living in a place where half the populaton doesn't believe in science.

seriously, imagine thinking injecting aluminum intravenously is safe and effective for anything @@gplus1000

This was never debated. It's scary to me that a lot of you people can vote.

Like Veritasium/Derek showed with the propeller car (built by a 3rd party) moving faster than the wind powering it.

I hate trusting formulas, which is one of the reasons I didn’t go into deeper physics for my PhD. The amount of solid state physics needed to do semiconductors for the most part can be excellently visualized, which means I can understand it 😁. Gaining intuition from an equation requires a SIGNIFICANT preexistng intuition based on something more tangible, in my experience.

@@AlphaPhoenixChannel That's not what I found in my degree. It's fairly straight forward to look at the formulae and see if it looks right with they key terms oriented in the numerator or denominator of a fraction. Sure, you may not be able to simply create a formula from intuition, (the capacitance formula of a parallel plate capacitor is one I would argue is intuitive) , but they are easy enough to look them up when needed.

Lmao you commented this 12 minutes after the video was posted, you must watch at 2x speed, huh?

I don't necessarily disagree, btw

Agreed, a really good dive into the concepts and excellent to have some practical demonstrations

@@BRORIGIN I watch most vids at 2x speed. It is not out of the question. Also the premise of this video is better than the rest, physically testing the phenomenon in question.

@@BRORIGIN Yeah x2 while I was catching up on my 1000 pushup routine

I really missed a superimposed image of the open vs closed circuit case.

Yes, cutting the wires was a great idea. What perhaps he should have said was it was important to cut the wires after having them connected first. You can't start the experiment with them cut, you need them connected at first to get steady state DC voltage drop across the switch before you close it. I've seen lots of other commentary on the original experiment which talk about the ends not being connected without making it clear they have to start off connected for anything to happen when the switch is thrown.

@@andy_taylor No you don't need them connected. You misunderstood the video.

@@romankalinchuk2750 they need to be connected initially or else the switch will have no potential across it. If there's no potential across it when it's closed then nothing will happen, you just end up touching two pieces of metal together (there may be a tiny electrostatic charge transfer). Initially before the wire is cut the switch acts like a capacitor, it's changed up to the full potential of the battery. When the wire is cut that switch ”capacitor” is still charged so when it is closed you will get a sudden rebalance of charge across it. But if you start with it disconnected you essential have an uncharged capacitor, so when you short it nothing happens.

@@andy_taylor Thats not correct. That's not how capacitors work. There is no current flowing though capacitors. Capacitors are not connected internally. The pulse you see comes from the battery, not from the switch and you are completely misunderstanding the video

its what Derek should have done instead of pumping some tabloid half-right half-pictured wish washy explanation of this for YT views

Simpler for you does not make it correct.

@@nineball039 Ok redditor, but that wasn't the point. Incredibly dumb and unnecessary to interpret it that way.

So this is closer to how experiments are actually performed, where the signal is broken down for different phenomena. The Poynting vector is something you talk about after Maxwell's equations and E+M in general. It is hard. Poynting vectors just tell you the flow of energy. I think a quick summary of what Veratasium was talking about comes from the fact that energy in a field is E^2+B^2 and that contains energy. Fields extend like this video shows so a little bit gets to the bulb first which is that early blip. Poynting vectors just ask if we know how the fields, relate, can we tell where the energy goes? They don't representing the physical processes in themselves.

@@nineball039 It's not incorrect either. It's a different point altogether. The experiment Derek picked is a poor fit for demonstrating what he wanted to demonstrate. I don't know that a "good" experiment exists; it's a fairly abstract point that's largely irrelevant in actual practice.

@@danielmorton9956 That's right, people have a really hard time letting go of the idea that energy is this tangible fluid-like "stuff', when really it's something that exists only in our heads because it makes solving problems easier. What's actually out there are electrons and electric/magnetic fields; the Poyting vector is a calculational shortcut that lets you say certain things without having to go through the full calculation.

A simple explanation. kzbin.info/www/bejne/fJWVfYSMnMiUbdU

He should have explained what would happen if the wires were cut. And how it DOES take one second for the lightbulb to reach full current. His explanation was incredibly lacking.

@@001variation Yes, exactly!

If he said that the minimal current in the bulb is just a result of wires reacting to changes in the magnetic field (which we observe on a daily basis) his video wouldn't be so "sensational". I consider his video as a complete lie.

@@uuuummm9 That seems really harsh. Explaining things is hard and it always involves some simplification -- it's easy to get it wrong. Fuck, take the standard explanation for GR involving heavy balls on a trampoline. Is that a lie? I mean you aren't really explaining why heavy bodies attract each other in GR because the only reason the bowling ball creates a dent in the trampoline is gravity. If you get into GR the actual explanation only works because it's a warping of space-time and it shifts the forward in time direction partially into the spatial dimensions. So is that a lie? If Veritasium's explanation is than so is it. But I think it's better to regard them both as poor attempts to explain a complex concept.

The wire literally just acted as an antenna. That's the answer. Literally basics of EE.

The machine you are referring to is called a Time Domain Reflectometer (TDR) and is used extensively today. Not accounting for your launch cable is a rookie mistake 😊. The way it works is that electricity will travel at a fraction of the speed of light in a medium depending on the construction (the makeup of the copper conductor) of the cable. The manufacturer of the cable will provide the type of cable that you can then enter into the TDR and “shoot” it to find the distance to the damage, or end of the cable. The signal sent out from the TDR will bounce off the damage and reflect back to the TDR. So if the machine knows the makeup of the cable it can determine the length very precisely.

I use to use a TDR on heavy jets. Works great. But few understood how or when to use it.

Time delay reflectometer? TDR

Time delay reflectometer would make more sense, but it is time domain reflectometer. en.m.wikipedia.org/wiki/Time-domain_reflectometer

@@owakulukem Got it. Thanks. “Delay” does make a lot more sense but of it is call Domain, then we will call it domain.

Very interesting. I was always aware that the signal could be analyzed to detect leeching but I never put much thought into what that actually looks like or consists of. Thanks for mentioning it. It stimulates my curiosity in terms of how that analysis takes place and what it looks like.

This ;) I'm a radio amateur and a few years back in our club we made a small device / electronic circuit that make very small but very powerful voltage peaks in a well behaved manner. That with help of an oscilloscope can test the quality of a piece or string (including connectors) of coaxial cable(s) . From the signal on the oscilloscope (top voltage of returning pulses and time from first transmission) you can then interpret if there are any (unexpected) shorts or opens, the dampening effect of the coax, quality of the connectors (if any), impedance mismatches, etc.Very useful in all kind of situations where you're no longer sure if your 'wire' does what it's supposed to do. For example to see if the cable to your antenna is still decent or if it's waterlogged due to the exposure to the elements or broken due to stress at its connector points or any other misfortune that could happen...

Exactly. That initial small step-response of current is revealing the characteristic impedance of the circuit. Since he knows both the wire diameter and spacing, it's simp,e to calculate that value and see how it compares to the 45R you calculated from the scope traces

Shouldn't that voltage also depend on how far the two wires are apart? Why would it 2.5V ?

@@renedekker9806 Yes it does. The characteristic impedance (Z) consists of an impedance L' and a capacitance C' propagating through the wire. It is complex and difficult to calculate, but if you match the series resistance Rs with Z it can be calculated really simply as a resistor division. Imagine 2 long unconnected wires like Brian did when he cut the wire at the end: Only now one wire is connected to the negative pole of the battery and the other connected to the positive pole using a switch and series resistor. As soon as the switch is turned on, there is a division of the series Rs and the Z. When Rs and Z are roughly the same you see a division of 50% , so 2.5V propagating along the wire. At the end of the wire after 1.6usec the 2.5V bounces and reflects to 5V which in turn propagates back to the beginpoint. So behind Rs (at the beginpoint of the wire) you should measure 2.5V for 2 times the propagation time ( 0sec - 3.2usec) and then it will jump to 5V. I must say, my initial 45ohm calculation for the characteric impedance isn't correct. I think it's more close to 5K - 10K, but can't accurately calculate it right now as the series resistance is not matched with the characteristic impedance.

@@liam3284 Yes I think it is. I don't know about the 1/3rd rule though. you should also keep in mind there is a resistor at the beginning and at the end in this setup.

@@foppe6849 -"Imagine 2 long unconnected wires like Brian did when he cut the wire at the end"_ - and now imagine placing the two wires 10km apart. Would the induced voltage still be 2.5V, or would it be less in that case? If it is less in that case, why would it be 2.5V if they are placed 1m apart? Wouldn't the distance between the wires need to be somewhere in the formula to calculate the induced voltage? I would expect it to drop off very quickly with distance. I would expect the 2.5 volt that you mention to only be applicable if the wires are millimeters apart.

The beauty of science and peer review is debates on facts by proof of hypothesis, and mutual respect is critical to all of it!

@Artificial Hobos I don’t think this is something everybody uses in their life and should know about from elementary.

@@michaelfoxbrass Too bad Fauci don't believe in that shit.

I see that as what content creation has always been about, nobody can simply address 7.8 billion people's ability to comprehend any given topic, so why not divide the load, right? That should be where everyone should want to be, as someone who can pass some kind of skill or information on.

@Artificial Hobos Hear hear. Not sure how it's like around there, but a large number of teachers here acquire their teaching qualifications not by their breadth of knowledge of a particular subject, but by passing a teaching exam. I mean, they may have tertiary levels of understanding, but is that truly enough? Are they keeping up with the pace of discovery in other parts of the world? That bothers me to no end.

The effect is lessened with distance. Therefore in a circle the distance would always be huge which would probably make the effect unmeasurable.

*boop*

@@spinnenente Fair enough, I just thought it might stop the interference or something between the wires and maybe be a more accurate result of measuring the speed. I know nothing about physics by the way! Just guessing stuff, but that's how you learn I suppose!

@@FriesOfTheDead *boop*

I think the initial blip will have a delay of 2r/c sec. and the steady state will have a delay of πr/c sec. (ignoring ripple). The harder challenge will be to make measurements. Placing of the oscilloscope will matter - at the center of the circle, or near the switch/bulb. Running long wires from the oscilloscope to the probes will also cause additional delay and interference.

So did you notice or have to be aware of a instant voltage in the transmission line when power was turned on many kms away ?

In a power grid, there are so many loads and generators, that it all balances out. If you only had one generator and one big load, the generator acts like a fly wheel storing energy, so all you would really see is a small slow down in the motor.

@@JakeHarris0 was more trying to ascertain the voltage he sees before the main spike in voltage of you’d have ever noticed it before when generator is turned on. Tesla has noted it When he turned on a power station but didnt actually know what it was. Seems you have too many generators power sources running on main lines to notice this or detect it.

Yep. In open wire, it's about 0.95

Ay was looking for a HAM related comment!

Always good comments to read on good videos! ty :)

Velocifactor?🦖

velocity factor in respect to the speed of light. thus .95 x speed of light.

Wow how old are you?

@@dorxlab 68

@@surfbyrd1 keep on creating brother never stop

@@surfbyrd1 nice

@@surfbyrd1 So you did this experiment when you were 11 or 12 years old? Respect, man. But.... are you sure? Where did you get the equipment and the physics knowledge?

It's a lot like ocean waves. The individual drops of water mostly just move up and down. They are just the medium used to transmit the waves. The energy of every wave crashing on the beach has come from a great distance at impressive speed, but the water is mostly the same matter as the previous wave and only slowly cycles in and out.

A simple explanation. kzbin.info/www/bejne/fJWVfYSMnMiUbdU

I had exactly the same thought!

would it matter if the wires were not stretched side to side. but instead, the bulb is on the further side of the battery?

@@ThreeWhiteSoldiers you wouldn't seethe effects of capacitance and inductance as shown in this video, since they would be acting parallel to the wire, so wouldn't get the shortcut path.

Derek says the light bulb still turns on with the wires cut, which is a bit of a stretch.

Agree 100%! I was lucky enough to have a science teacher with his energy at my high school way back in 2000. Heaps of his students have him on Facebook so we're still in touch after his retirement! :D

No expert had any doubt about this, and no such thing was claimed either.

@@enjufi If it was so clear and it do not claim incredible things, why so many experts got chocked by this video ? Why so many expert claim that the video was wrong and/or missleading ? I'm not saying that the explaination of this video is new, but the Veritatium video was at best missleading, and clearly wrong on some points.

Hi Pierre, in the links provided by Derek at Veritasium, you will see a presentation showing an overlay of theory and measurement as backup proof. I was the one who did the simulation and measurement for Derek. Hope this helps, it's actually a fun measurement. You can turn on the "bulb" much more that what you see here if you match the transmission line impedance to the bulb resistance. Doing that means the voltage on the bulb goes to half of the applied voltage almost instantly, and then jumps up to the full voltage after the propagation time associated with the length of the wire and the speed of light. The resistance of the wire used in this experiment is going to be a factor in the result. I did a scale model that was shorter and used thicker wires so I could neglect resistance.

@@rsa4510 Thank for your response. I do not pretend that the tehory is false, and every video I saw on the subject talk about the impedance matching, including this one. I understand that the idea behind the trought experiment was to show that electromagnetic informations travel at the speed of light in all direction, But the setting was very missleading. Everyone that work some time in electricity or electronic know that all wires are antennas. If you forget to connect a resistor to a disconnected low voltage wire, the current will vary randomly inside. Unless you use a very strong electromagnetic feld, or a filter, you will not be able to command that wire current from outside, because the ambiant noise will be stronger that the command. So, unless you have perfect (and impossible) conditions, you will never be able to light the bulb without additionnal component to create a very strong field and/or a frequency filter and amplifier. The bulb will either: - always be on (if all current turn it on) - flick on and off randomly (if current variations turn it on) - Turn on after the light speed delay (if realistic current count). If you find a way to make a wireless transmetter/receiver that work without the need to create a powerful signal on a precise frequency for the transmitter, and a filter and amplifier for the receiver, you will become rich. Edit: I just understand that the Veritasium video is in fact a commercial for a brand of wireless LEDs. It raise a lot more questions...

Veritasium deceived his audience by showing the visualizations for a stable state that is only reached after significant time have passed to somehow justify his wrong statement about power getting to the lamp directly at speed of light which is a very different situation. He didn’t show actual visualizations for his “correct” answer.

@@noop9k Yep, ElectroBoom and Dave did videos that explain this at a higher level. Essentially you can think of the wires on each side as transmission wires.

he did say that the lamp has to turn on with ANY current. the problem was that this hypothetical situation can be easily mistaken by people as a very intuitive expectation while it isn't; a light wont turn on with any current, nor having "any" current is "any useful" for other things. he just made a big capacitor. But I suppose the real reason for the video was that energy moves through the electromagnetic field instead of tiny things moving inside of the wire. which is right.

@@falahati > he did say that the lamp has to turn on with ANY current He actually said "the light bulb has to turn on immediately when current passes through it". Maybe because I'm not an engineer, but I thought he was emphasizing the "immediate" part, not saying that any amount of current will turn it on.

@@marko1395 He didn't need to emphasize the any amount of current part in emphasizing the immediate part. Bulbs fade on relative to their load, so if it comes on immediately, it comes on under ANY load

Like waves hitting a wall, start moving back

@@RetroMailToday there are no walls at the end tips. Simply since there will be more electrons they repel each other backwards

@@davidabdollahi7906 No its due to the fact that wires have some inductance and capacitance. So it takes some time to reach RLC steady state until which they resonate.

@@ashwinalagiri-rajan1180 When you use transmission line theory to explain this "bouncing" effect, it is easy to think in terms of waves bouncing back and forth from the end of the wire in much the same way water bounces off objects in a pond. The interference of these waves with each other causes the distinctive "bouncing" current and voltage patterns. They teach us in EE school that RLC circuit behavior is a gross simplification of the behavior of electric circuits that is only valid when the circuit features are much smaller than the signal wavelengths. And we only use RLC equivalents for circuit behavior of real transmission lines at a point. AlphaPheonix's explanation based on charges, electrostatic, magnetostatic and electromagnetic theories are very good explanations and can explain a lot more things that happen in the circuit that are way beyond the ability of RLC circuits to explain.

@@renedosr Alright I think you're more versed in the subject so I accept your answer.

And of course, to make the point of the distance and capacitance obvious - it would be cool to see the wire strung out in a big circle.

With AC you would only transfer current according to the characteristic impedance of the line. With the small wires some foot/meter apart, the characteristic impedance would be close to 1 kOhm. Hence not much power would transfer. (Perhaps if you match the frequency/wavelength to the length of the line, as you do with antennas, you could get some additional benefits?)

Exactly my thoughts. It is practically a very long antenna. With AC at a resonant frequency, you would be able to transfer energy. It would still be a lot less efficient than if you actually connected the ends of the antennas.

When I saw Veritasium's setup I thought: ladder line

It's coupling between the antennas before the DC component is established. Near-field interactions are frickin' weird. Feed it with a 1 kW signal of about 1.5 kHz. Sit back, and wait for the FCC to arrive ;)

Also Derek explained it in a very very misleading way. He doesn't even mention that the lamp only turns on slightly until a bit later in the video and the way he explains it implies the lamp intensity goes up linearly or smth like that. This video explains it very well without the stuff about the field carrying the energy which while true is not a very practical explanation.

Derek could have but it would have been less dramatic.

​@@markoproloscic4492 Yeah I agree. Derek made it sound like some quantum effects were controlling the wire, but it's a lot less complicated than I thought

@@markoproloscic4492 That's because it's a thought experiment, not a real one. He clearly states, that the imaginary lamp turns on from any current, and that it doesn't receive full current nearly immediately.

@@enjufi It's not wrong inside the design of the experiment, but for the sake of educating people it basically ignores that most people are already familiar with radio transmission. The best way to tech people new ideas is by connecting them to things they already understand and then expanding upon it. Derek tries to imply that some sort of barely understood phenomenon is causing the effect, when it's basically just a broadcasting and receiving antenna.

A simple explanation. kzbin.info/www/bejne/fJWVfYSMnMiUbdU

that was the whole point of Derek's video - that the energy is around the wire. When you use coax you forbid all of that and then this whole effect goes away and the electricity has to flow the 500 meters before anything happens. He could emulate that by moving the resister 10 meters further away.

@@idjles I dunno, i've sent data wirelessly from TX to Moscow with

I was wondering about the impact of insulation/shielding on the wires as well. But @Idjles Erle addresses that, I think. Yet, something about both Veritasium’s and Phoenix’s videos still “feels” incomplete to me ( I have ZERO electrical engineering or physics education, but have worked extensively in telecom all areas most of my life). So I’ll watch Phoenix’s part 2 to see if/how it addresses that “feeling”. I learn by inferences and logic of these videos - and even if I don’t/can’t do/understand the formulas involved, the practical applications of the facts/concepts presented are intriguing and compelling enough to explore !

Levels of physics seem to go infinitely deep, ask any Quantum physicist. For this experiment, it helps to include the physics that electrons don't literally move through the wire. They PASS their energy to the next electron and so-on down the wire. More like bumping one ball at one one end of a long line of touching balls, and measuring the time the last ball moves. The concept that electrons CARRY energy, and are NOT the actual energy, is usually moot in practical applications, or classes for that matter.

@@genewitch the speed of light is not a limit...in quantum physics it's called instantaneous action at a distance and its faster than the speed of light....it's instantaneous hence the name....

Yep, had to rewind back to confirm the first time I noticed it lol

In his defense, if he performed the experiment, it would become obvious it was a total clickbait because the transferred current is completely puny and in great most cases completely irrelevant.

It's truly inspired people to prove him wrong, just like flat earther's videos inspire people to prove *them* wrong

@@LeavingGoose046 Not quite the same thing, since Derek wasn't really wrong where people thought he was wrong. The issue wasn't about correctness.

@@jacobshirley3457 The conclusion he led you to was wrong, because he purposefully mislead his audience. So he was right, only if you knew the material beforehand and were able to know what he tried to say.

@@LeavingGoose046 It is misleading, definitely. Confusing, for many. Purposeful, I'm not sure. But it's still disingenuous to compare his video and the videos of flat earthers in that way.

And he actually oversimplified the problem a lot. While Derek basically mislead to make people angry, for viral effect.

@@noop9k I wouldn’t for a moment say oversimplified. He simplified to a level he was comfortable explaining which was perfectly sufficient. Simplification is, to an absolute, necessary in physics because otherwise you’re looking at a number of things that approach infinity, yet the returns for each newly considered factor becomes infinitesimally important. But yeah, you’re right about the second half. There’s a reason he is the biggest physics channel I guess. He intermixes actually good, informative videos with ragebait/confusion bait. For example, the counter steering video explains a cool and important part of classical mechanics. I forgive the bait videos because it gets people into physics, but it does mean they come away misinformed… not explicitly due to him, it’s just that when you portray something the way he did, it’s very easy to misinterpret if you aren’t already knowledgeable in the field.

Also known as the *velocity factor* .

Rf engineers and radio hams know all about this and make use of it in antenna designs and stubs which are particularly useful in phase matching or cancelling. The vector voltmeter can be used to make the measurements.

Good co-axial cables have a Vp of about 0.8 or more, i.e. 80%

This all sounds like a different language

@@ToriKo_ "This all sounds like a different language" That it is. Rather a lot of what you learn in basic electronics has to be revisited. It is still basic electronics but with some unexpected twists. At microwave frequencies, wires just don't work very well and so you use hollow tubes called waveguides and the two polarities will travel inside the tube but on opposite sites *as if* there were two wires, but there isn't. Velocity factor means that the wave isn't actually traveling at the speed of light. The wave triggers the next electrons to start moving, and their moving advances the wave, but the presence of the other wire causes inductance and capacitive effects to slightly retard or delay the advance of the wave. It isn't just wires that do this. Light actually slows down upon entering glass or anything transparent; the degree of slowdown is also known as the refractive index. It is very nearly certain that the photons that pop out the other side of a pane of glass are not the photons that entered. The energy wave travels through the lattice structure and pops off a photon on the other side with the same angle of incidence as on the arriving side; this is how prism and lenses work. Well anyway, it is all very interesting stuff.

Michael Schmidt - that is false; knowledge is not truth. Moreover whose knowledge do you know is truth? Aristotle 'knew' that a constant force produced a constant speed. The Catholic church and many other religions 'knew' the earth was the center of the universe. The Chicago Sun Tribune 'knew' Dewey beat Truman. Donald Trump 'knew' he won the 2020 election.

@@nineball039 Oh, don't be pedantic

@@nineball039 Thinking you know != knowing.

@@isodoublet Knowledge is thinking you know which is not truth either as the OP claims.

@@nineball039 "Knowledge is thinking you know" No, it isn't.

Derek continues the long tradition of clickbait in physics, which was started by Archimedes, who said: "Give me a lever long enough and a fulcrum on which to place it, and I shall move the world."

Before those, we had arc lamps, would those be considered spark gaps?

Careful about the diodes, they first are SED, which stands for smoke emitting diode.

@@KrupyFren enough current and the light comes at the same time XD

just like how every diode is an LED, not in my experience. Most times they just silently die (no more current going through) I ones that actually exploded tough. Never I have seen on shine.

Um, afaik every diode really is an led (as well as a solar cell) thou. Some just don't shine in the visible light range.

i don't rate Derek's intelligence. i think he makes too many assumptions. This is one example, climate change is another, and also he takes for granted that vaccines being safe and effective ( which is absurd for anyobe caring to do detailed analysis).

I wasn't a fan of Derek's videos for all the ways Mehdi explained in his excellent ElectroBOOM video. He uses outlandish language, like "what you were taught was a lie!", when it wasn't a lie at all, just a simplified model, which is PERFECT for a school education. And Derek's video really just served to confuse people and make them feel less confident in their perfectly acceptable understanding of electricity. I'm glad you're feeling better now!

@@dantheman1337 can file your response in the nut job bin. Two statements and two red flags.

Me too, couldn't sleep for days thinking about it

​@@dantheman1337Those "assumptions" you refer to are based off of overwhelming evidence from extremely high sample sizes. Please stop this science-denying insanity.

I agree completely. Derek was not wrong, but not completely correct either. The whole thing was enlightening. :-)