This Drill Powered Spool Proves Me Right

What do you think? Have I convinced you? You can also discuss this video on REDDIT: stvmld.com/8asj3e4u

I’m convinced! Give the man 10,000 pennies.

Damn it! I'm starting to get more convinced by your theory!! Is it the start of losing my 10000 cents?! We shall see! But this video was quite clear and understandable. Thanks!

7:50 Not only can you see the fountain rising up on the left but you can actually see the pile being pushed down as well. So there is a clear force being applied there.

I used to watch the anchor chain do this whenever we dropped anchor on boats, when I asked about it the experienced sailors told me it was my imagination or not to worry about it. Glad to see someone finally proved what I observed as a kid was actually real.
It isn’t just bead chains, works with bigger chain too.

Nice, and I love the surgical empiricism here - dividing this problem up into pieces has not always been easy - I like what you did here - for me, the simulation where the bottom of the pot is removed is the killer moment I think (and that the simulation can provide force data). Nice work!

This feels like that stuff we read in history books about mathematicians, and scientists in general, throwing challenges at each other; it's awesome!

This whole bit is easily one of my favorite internet moments.
The simulation made a real difference to me. You ought to just put the beaker on a load cell and record the down-force directly.
How long until we get a Medhi/Mould channel?
Call it, like, "Mouldhi"

Nice steve, maybe you could use cotton down the pot to cushion the chain and check if the fountain still happens.

With videos like this by you and Mehdi, I find myself feeling just a little bit romantic about the scientific method. Devising new hypotheses, developing new experiments to disprove them, admitting and correcting mistakes, changing minds with friendly competition, all in the quest for understanding. Thank you both for advancing the field.

You have won back my vote of confidence. I think the real phenomenon is how each of us can have our minds and perception changed with a good argument and it's important to avoid a "one and done" approach to evidence and arguments. I am team Mould again... pending further evidence.

The rivalrous banter between you and your nemesis reminds me of a quote from the movie Heaven Can Wait…
“The likelihood of one individual being right increases in direct proportion to the intensity with which others are trying to prove him wrong.”

From the very beginning (when I started watching these videos, that is), I intuitively guessed that the lower flexibility of the bead chains was key to understanding the effect. As a child, I loved to play with such chains because of how interesting it was to twist them into different shapes. If you tie them into certain knots, you can actually get them to retain their shape in surprising ways.

Man I love this new trend of science youtubers doing "live science" and trying to proof each other wrong! Always restores a bit of my faith in humanity ;)

You've changed my mind; was agreeing with Mehdi's explanation after your initial videos. Your new demonstrations are great. Good job!
And kudos to Mehdi for not letting you throw in the towel, we need more of this!

Interesting points, I used to be industrial abseiler and found that I also had the Fountain effect when throwing my rope off tall builds. I used to have the rope tied in daisy chain and rope was 11mm thickness. I agree with your kick back resistance. Thanks for the video. All the best. Phil

We need the gods of CZcams physics to come in a finish this for once and all. I call upon Veritasium, MinutePhysics and Smarter Every Day to join in

I LOVE this back and fourth feeling where I have been "pretty sure" both parties were right respectively after each video. The realisation that I was wrong is humbling.

I just want to say that I love this back and forth “CZcams science drama” and it would be awesome to see more creators challenge each other with different hypothesis. I suppose it might be hard to find a surplus of topics to argue, but if it’s possible I’d love to see more of this!

Great job. Kickback maybe not the most intuitive word to describe it for me but this certainly makes sense. The inertia tries to bend the chain when it pulls away and the chain presses against the ground when it bends. Awesome video.

5:15 the beads have to be horizontally constrained and stacked vertically. He’s losing a ton of energy from the chain whiplash. The chain wants to move side to side but if it can’t it must go up. Unless the energy is great enough.

I’d love to see Steve’s Amazon account for the last few months, just loads and loads of chains

I love how this is the best """""drama""""" between two youtubers, but instead of insulting each other you're fighting hypothesis after hypothesis, admitting mistakes and challenging each other to disprove the other person better than last time.
Yay for the scientific method!

this debate inspires me to study physics more precisely and get all the pieces together. i have a hand wavy understanding now. Thanks steve and mehdi!

I absolutely loved this video! It feels so real, you guys are haveing an actual public debate, to test your theories and continue to learn. One thing that annoys me is when the modern scientist show "it works in the computer model!" But no real debates or tests.

I have to admit that I was convinced when I saw the horizontal demonstration. After you reframed it and explained it I realised how two very different things can have the same perceived effect

This is getting out of hands, I see a global chain shortage emerging

7:56 this convinced me. Also, splitting into two parts and narrowing down what the Mould effect precisely is was a very good idea.

Great video! I might have another interesting idea: The falling end of the chain speeds up because it is nearly performing a free-fall accelleration. As we've seen, a chain wants to maintain its shape, so every part of the chain also wants to keep up with the increasing speed. At the beginning, the rising part of the chain inside the glass is so short that gravity forces and inertia only have a small effect. So what if we look at the top of the fountain as being a half circle? Objects moving along a circular path are pulled outwards by the (imaginary) centrifugal force. Because the lower half of the circle is missing, the sum of all centrifugal forces points straight upwards. I think this might be the reason why the top of the fountain is rising. The centrifugal force at the top of the fountain is pulling the rising part of the chain higher out of the glass. The fountain is growing until the gravity force of the rising part (which becomes longer and heavier as the fountain rises) matches the pulling force of the fountains top. Having reached that "point of equal forces", the fountain will remain a stable hight until the end of the chain. Does that make sense?

The simulators did a great job tbh, they deserve the credit

I've been an admirer of both of your channels for a long time, and I must say, you both have a wonderfully pedagogical approach. I really appreciate your content and your commitment to the scientific method.

Yeah, this video was much better than the first and convinced me you are right. The only thing in medhi's video that had me going was the spaced chain part, but the way it was addressed here cleared it out. The chain don't rise, it only keeps the shape it had.

That's incredible. I love that you both go after this very seriously.

Seeing the chain try to kick through the bottom of the pot when you removed the floor in the simulation was what really convinced me

Ok Steve, you've won me back. I did not notice the falling arc in Mehdi's 2D experiment, or how dramatically he imparted the arc in his beaded fishing line. Both valid points. Your 2D comparison of the ball chain spaced out versus bunched together specifically shows the need for the kick-off effect to increase the height of the arc. I'm convinced...again. Are we done yet?

Ok Mould. You've convinced me that the height is due to both the resistance to bending and the fact there's a base to push off of. Well demonstrated. The simulation was what pushed me over the fence when it depicted the spike in downward force right before the bead came up.

Thank you for featuring my simulations.

I love CZcams scientists making the new modern “drama” videos debating science.

There's an easy explanation as to why it decreases (5:20 mark). The chain used up around the end is further back than the fountain origin. As such, gravity + friction cause the lag to a much greater degree than at the start. More force is required to maintain the shape but more force is not being applied to do so. Check the equation and see that the force required increases in a linear fashion.

just my 2 cents: amazing channel and I've made a point to try and watch one a day so I can retain what I learn. Thank you for your hard work in delivering these concepts in easy ways to understand :)

If you hold the Motorized Spool™ on a higher level than the beaker, thus pulling the chain up rather than down, will there be a peak/fountain that rises above the spool too?

Wait, we need Destin from Smarter Every Day as a judge as well.

I think you have the best simulation so far at this point. I have to side with you and believe that there is another force behind the chain in creating the fountain. Incredible detail, I think you have it my friend.

This is the first I've heard of this phenomena, but my immediate intuition was: it's due to lag in the chain at rest rotating into alignment with the direction of the chain pull. In the case of a traditional link chain this would be from a combination of angular inertia and friction between links. If the chain is travelling faster than the time it takes for the 'picked up' chain link to rotate into alignment, the non-aligned link rises up, I.e. a 'kink' travels up the chain. If the same happens with the next link behind and so on, it results in a series of kinks that, if they don't straighten in time, create a rising wave. The misalignment might be small between each link, but combined they form a curve. It would be interesting to do duplicate drops with a link chain, first dry, then lubed, to see if there is a difference in wave height. I suspect the lubed one would create a lower wave, despite the potentially reduced friction over jar lip allowing a faster initial chain speed. I also suspect the layout of chain in a pot might effect things. I.e. I wonder if a chain laid out circles around radially around the circumference of a pot would create a different /more consistent height standing wave than one lapped back and forth into a pot, due the different angular change their links experience from at rest vs. direction of pull.
I'll caveat all this by saying dynamics is not my area!

14:11 "Having this disagreement has been fairly enjoyable" This is what I love about science and more specifically science on CZcams. Its so great to see people completely disagree on things and enjoy themselves while doing it. Just like Veritasium's recent video's on the vehicle that travels into the wind. Keep up the good work!

I think the interesting point is at 9:49 when the gravity is removed in the simulation. The chain line being pulled out drops below the level of the base line, without gravity this can only mean it was pushed down. If the bottom was still there then that push would result in a reactive force from the bottom of the pot, proving Steve correct in saying there is a "kick" from the pot.

PLEASE READ: Using the spaced beads in that way is wrong in my opinion. if you just let the beads off the edge of the board, there is no upwards force acting upon the chain. its only being pulled to the side and down. But in a beaker/cup. the chain is forced to move UP out of the cup. therefore it initially creates and upwards force that then increases as the momentum of the falling side increases.

Bravo Steve. This is excellent. I am now convinced by your explanation, where previously I found mehdi’s video more convincing

Oh man, that howNotToHighLine plug! As a rock climber myself, that guy is seriously helpful in showing what gear can handle.

I just watched the previous video like 5 minutes ago. CZcams recommendations are now so advanced that relevant videos are not only recommended but made when I would watch them

Probably pretty late to this discussion, but I actually think that the demo at 5:46 disproves Mehdi's theory on the upward force being a reactive force to the downward falling chain.
Before this, I thought that it could be a combination of both theories. Using Mehdi's theory, the height of the peak is dependent on the speed of the falling chain - I interpreted this as the acceleration of the chain leaving the pile needs to match the acceleration at the equal point in the falling chain. This would give rise to the force required for the chain to rise when leaving the pile, and thus leading to the kickback force (dependent on the chain rigidity).
However, the 5:46 demo shows no matching upward velocity, regardless of how fast the chain moves downwards. Thus, currently siding with the need for the initial upward velocity, followed by the kickback force to raise this peak above the lip. And as the upward velocity increase, so does the kickback force, raising the peak.

I think the experiment with the chain bunched up on a surface shows the bunched up chain moving downwards, especially at the end. This would indicate the "kick down" effect. It's most apparent in this video where you're comparing the bunched up chain with lip together with the chain more loosely laid out on the other side about 8 minutes into the video. I think you describe the effect as the recoil on the stationary chain.
Mehdi makes a similar experiment with a similar effect his second video at about 9 minutes in, but it seems the chain being pulled hits the "pile" so it's not as clear cut on that video, but I think I see the pile moving there as well.
I think you're correct about the kick back. Love both of your channels. This is good.

I first watched yours, and I was convinced. Then I watched Medhi's, and I thought yours was debunked and I was convinced of his. Now I see your rebuttal, and I think his is debunked and am convinced of yours again. What this teaches me is that I almost always believe the last person I talked to, and I should just shut up and wait for the community consensus to establish.

Mould-Effect surely caused a very pleasant "Chain-reaction". Love to watch your guys intellectual discussions.

The lever effect Steve mentioned was close but it would happen even if you don't have something to support the chain.
Because most of the mass of the chain is located in lumps and those lumps are connected by stiff rods any moving bend in the chain causes a repeated lever action where the inertia of the lump resists the pull of the accelerating side. This creates a lever that pulls on the other side of the bend, accelerating it a little.
For the peak of the chain experiment this has little to no bearing because the energy to do this comes from the side accelerating down, meaning that the total forces don't change. The bend is different at the base, however. Instead of the forces opposing each other and negating each other one is thrown essentially away from the system, causing the other to act in a measurable way. In this case that means that when the lever action occurs where an upright chain pulls on an either horizontal or parallel chain the lever thrusts one end downwards below the original bottom line as the chain attempts to maintain its shape. This creates an upward force on the chain at the expense of the chain's elevation, and when measuring the forces in a situation where the chain is resting on a surface this looks like the chain is pushing against the floor even though no pushing is necessary to achieve the upwards force, as the force downwards would give the upwards boost anyways.

It looks to me like the reason the stiffness of the chain imparts force on the bottom of the bot is because the chain's resistance to being bent means that when one bead in the chain moves upward the next bead at rest is "pushed" into the pot slightly as it at first resists bending. If you think of the beads as being connected by tiny teetertotters or seesaws, it becomes alot easier to understand what appears to be happening. When the first bead is lifted, it's partner bead gets pushed down into the bottom of the pot due to the stiffness of whatever happens to be connecting the beads together which is in addition to the pull of the chain itself in the other direction. Pull one bead up, and the other gets pushed down.
Furthermore, the bit of wobble in the actual position of the chain is explained by this as well. If you were to take a slightly flexible piece of wood and then bend only one end while holding the other in place, then let go the other end will suddenly flick as the entire piece of wood attempts to return to its original shape and chances are it'll so do quite violently. So as the beads in a chain continue to be pulled and are finally lifted from the bottom of the bot (or from the other beads farther down the chain they are resting on top of) the chain's stiffness again causes them to flick back into place and wobble- hence the very chaotic movements of the fountain.

My favorite part is how you selectively break the rules of physics in the simulation to reaffirm your hypothesis in an intuitive & visual way, amazing work!

Very nice demonstration 👍
Good thing you added that paper roll, otherwise you wouldn‘t really have seen how high above the ‚starting point‘ of the chain it currently is because of the extra way it had to travel. But i guess the simulation is a good way to prove it too.
Anyway i‘d definitely say you have a goot point there. 😊

I was more convinced by Medhi's explanation compared to your first video, but this video was very convincing, especially the sideways experiment on the floor where you made an object act as the lip of a container, as well as how the height of the fountain was different between the spaced out chain and the piled together chain.

Crowdsourcing science - freaking love it. You have 2 guys debating and others essentially peer reviewing. This is how you get to answers _really_ fast.
Love it, love it, love it!! This is brilliant.

I would be interested to see some experiments on a surface that would absorb some of the peaks in the normal force (foam, rubber, a pillow?) instead of reacting with a kickback force, and see how it makes a difference vs a hard surface.

This entire chain of videos-pun entirely intentional-makes me think of how scientists of previous, pre-CZcams times would hash out such disputes, often to the benefit of science. Now we ALL get to be a part of it! I love this!

I watched Electricbooms, video.
In each of the examples on the floor, there was a friction capable of helping each chain reach the Mould effect. The answer may fall under fluid dynamics.
If my theory is correct, it would be similar to racing cars running in a line. In a group, they cut the air more effectively. All the cars in a line can move faster and more efficiently through the air resistance. They create their own onvelope of air and all cars in the line benifit. In contrast, if a car tries to leave the line, there is air flow trying to force it back into line. Anyone who has tried to pass a big rig on the freeway has felt the air the truck is pushing their car.
In the case of the ball chain, the shape and speed of the chain allow it to slip through the air like cars Drafting each other. It is why the chain can fall faster than other objects at terminal velocity.
When the chain is moving slower, it has less of an effect on each ball. The arch is much smaller if present at all. Cars need to be doing around 70mph to do a proper draft. The faster the chain gets moving, the greater the difference there is between the outside force of the resting air and the air inside the envelope that the motion of the chain has created. In higher speeds, outside air should push the individual beads back into their slip that speed is creating.
If my thought on this are true, it should not work if done in a vacuum.
Additional testing could be done on more aerodynamic, fluid chains to see if a greater effect is seen or, if an adjustment to the aerodynamics of the existing success could give a more efficient/higher arch.
The surface in the cup is not firm enough for the force in the cup to have an effect. All the balls role all over the place in the cup. Their is no firm push that I see.
Oddities in air or a brief change in the speed of the chain caused by imperfections in the ball chain could be the cause for why there is sometimes a second loop or a less linear line. Imperfect flow causes a dirting up of the flow of air causing brief deceleration that is then overcome by gravitational flow.
Just some thoughts.

So, from your theory, should you place a soft bottom to the pot (like a sponge), the chain shouldn't raise as much?
I would be interested to see it ^^

9:46 I had an aha moment. That simulation really helped me understand your view on the kickback force and why the rigidity is so crucial to the kick back happening in the first place.

Curvature of coils in pot constitutes a latent wave which imparts an additional along-chain torsional force (a coiled bead-chain will rotate along its length in order to lie in coils). The force of weight of chain falling to floor outside the pot transforms these latent waves (remember the bead-chain is not absolutely flexible, so it cannot bend at 180 degrees) and the slight torsional twist in the chain into a vertical one. In other words, the sudden subtraction of nascent wave energy and torsional twist energy in the chain get converted into along-chain energy. The released nascent energy is greater than the force of gravity acting on the descending end of the chain. Therefore, the chain ascends until the nascent coiled and torsional energy have been 'uncoiled' to the point at which they lose out to gravity.

Watched all the videos, and I agree with Mehdi. The energy to lift the chain is not comimg from the pot, or any other surface, it's coming from the chain itself.
As the Cambridge people explain, if 'link 1' is pulled in a certain direction, it forces 'link 2' to rotate around its center of mass. As a result, 'link 3' is pushed in the opposite direction of 'link 1'. Because of the law of inertia, 'link 3' does not yield so easilly, and therefore serves as a base for 'link 2' to push off from. The push on 'link 3' will cause it to rotate as well, but in the opposite direction of 'link 2'. A moment later, when 'link 3' is starting to get pulled in the direction of 'link 1', 'link 3' is forced to reverse its rotation given earlier. Due to the conservation of momentum, this requires a relatively large amount of energy, and this extra energy makes the effect on 'link 4' bigger. This extra energy that it takes to 'whip' (yes, this is a similar but reversed effect as that in a whip) the chains into the right direction will serve as a counter force to the force of gravity, thereby explaining why the chain has its critical speed less than expected.
So, this effect causes a momentum in the links, and due to the conservation of momentum, it will form an arc in the chain. The radius of this arc will depend on the mass and 'stiffness' of the chain, just like the bend radius of rivers is depending on the width / depth. Note though, that the behaviour and bend radius of the ball-chain is different when the links are compressed or pulled apart!
And the fact that in Steve's video the 'stack' of chain on the ground is finally pushed 'down', is a result of the down curve of the chain making room for itself, not a result of the chain pushing off from the 'ground'.

"Seeing as to how this thing is already made, I might as well try to simulate a gory chainsaw accident"

Oh, we made the same experiment with a drill in 2012 (see our video 2016 in Russian, with English subtitles). // If you want to know historical details about the discovery of this phenomenon, read here: en.wikipedia.org/wiki/Chain_fountain

The simulation was crucial for my understanding. Once I could see the loop first dipping downward when the bottom of the container was removed, I immediately grasped what you were saying about a "kickback force". Really well done all around.

I think there are two effects occurring concurrently that is causing the chain fountain.
The first effect is the acceleration of the semi rigid chain. To get out of the pot / pile the chain
must accelerate upwards to match the speed of the falling chain V(up) = V(down). As the
chain has little to "no" stretch this must be the case. To transition from up to down the
chain must turn. With a supple chain there is "no" resistance to changing direction as there
is no mechanical limit to how the chain can bend. 180 degrees is not an issue (yes this
implies instantaneous acceleration from up to down but as it is passing as an arc over the
lip of the pot the acceleration is slightly less than instantaneous as it is accelerating around
a curve not a point). This is the effect observed in a string or the chain with the spaced out beads.
The second effect is inertia. As the upward traveling semi-rigid chain is accelerated
downwards it cannot change direction as sharply as a more supple chain can. As the chain
moves faster and faster it reaches a limit as to how sharply it can accelerate around the
edge of the pot with the inertia and the resistance to bending resulting in the lifting of the
transition area from the edge of the pot and it reaching the highest point when the chain reaches
terminal velocity. TMMV

I've watched all the videos and was on the fence until this one. You have convinced me that your hypnosis is most probable, Mr. Mould. Thanks for the discussion and brain excercise.

My money's always been with you steve! In all seriousness though, these youtube "arguments" that are solved through experimental/empirical methods are great, super cool to see science resolve disputes in real time.

The horizontal experiment with the drill, where the beads were spaced out versus not, was quite convincing. Nice video.

The force from the momentum of the falling chain (which increases due to the mass of the chain outside the beaker increasing with the length of chain) pulls with enough force to cause lift of the internal chain, in relation to the smaller length and mass of the inner of chain being lifted. Force needed to lift an object straight up is equal to our greater than the weight of the object. In this case lifting the chain above the edge of breaker would probably be a force greater than the weight of the chain inside breaker that is being lifted, or in the air.
The upward velocity of the chain also decreases over time due to the downward pull of gravity. The exact peak of the chain is velocity of 0 for a millisecond, where gravity has stopped the upward velocity movement before starting the velocity to go downward in motion. This decrease in velocity also decreases the momentum and force of lift as the chain approaches the apex.
The are other factors involved, but this was the easiest way I could explain it with out writing a novel.

I suspect the fountain results from 0) initial state with a lip that causes a 180° change in direction from up to down, 1) acceleration of the chain as it initially falls, 2) as the chain accelerates, the impulse imparted to each ball also increases, requiring a longer period for gravity to counteract it... which means the fountain will grow until terminal velocity/equilibrium of the moving section of chain is reached.

One thing about the horizontal simulation, is that the movement “down” isn’t immaterial. You would need to compare that to a a chain actually falling down, but lower the beaker as you do it.

This video finally made me understand the Mould effect. In order for the chain to be pulled up from the base, it needs to change the angle of the connecting rod between the two beads which has just enough resistance to push the bead into the base harder, causing it to have a higher kinetic reaction.

I think ElectroBoom was with his approach to the reason for this being inertia of mass. As you know you can split every velocity in 2 vectors perpendicular to another. Since this is a chain, you can split the links up and look at them seperately. Now assume a coordinate system and make one axis follow the direction of the chain link and the other perpendicular to the chains direction.
If you now drag the chain along on the ground, the velocity vector will always be 100% of the total velocity long (obviously).
Now do the chain drop experiment: there are 3 stages (straight upwards, straight downwards and changing). We know how the velocities look during the upwards and downwards phase. But in the "changing" phase it is different. Because one: the chain link already starts this phase with an upwards velocity that is equal to the total velocity of the chain and two: it will experience a constant force in the chains direction - so along the arc.
So as long as the chain is accelerating the speed vector of the chain link perpendicular to the direction of the chain is getting bigger (since the chain link is getting forced along a curved line). A bit like a vector of centripetal force would look like. This changing outwards velocity is the reason the arcs radious to get bigger.
I think the hight in which the arc starts is also determined by the velocity, since then upwards component of the chain link traveling upwards is bigger with higher velocity and therefor it takes more time to cancel that upwards component of movement. When the speed is constant in an optimal scenario the hight should not change.
And for 4:47 - the lengh the chain travels to the edge of the board gets longer and that changes the direction the individual chain link goes during the first phase - lowering the upwards component of the velocity.
sorry for the bad english

Coming back after Mhedi released another video!

Start a fountain from a high place, then after it starts to fountain drop the pot into freefall. If the pot then accelerates faster than a dropped pot with no fountain then there is a kickback. The said kickback would push on the fountain forcing the pot downward faster. This would also exaggerate the fountain length as well. Might answer some of the questions to try this experiment.

Dang, Steve, I'm really glad you made this follow up. I was one of those that felt there were a lot of unanswered questions. In a perfect display of the scientific method, you've strengthened your arguments substantially. As you say, it's not about winning, but about finding the truth and adjusting our positions based on new stronger evidence.

Never doubted you dude! Good work!

My intuition would be, it has to do with the concervation of momentum of the chain initially being pulled up into the air, and then having to redirect and fall downward due to gravity. If you have the chain in a beaker initially, you can see that the chain will on its own impart an upward monentum as the chain in the beaker starts out being lower and lower than the lip of the beaker.

As a mechanical engineer, this debate has been a real treat. Shows how difficult classical mechanics can get. Medhis did an awesome job, but I'd declare Steve the winner. Simulations always have to be analysed carefully, however I think in this case the core of whats going on mechanically is represented and the consequences we learn from them unlock the physicis of whats going on.

You should put the bead container on a weight measurer to confirm the kickback force

Here is the thing. If the chain has any "stiffness" at all, the bottom of the chain thats leaving the pot can be seen as a part of the chain (of arbitrary lenght) that feels a force (being pulled up by the 'previous' part of chain) on only one of its sides. Since that part of the chain has non-zero stiffness/rigidity it will start turning around its centre of mass. But its either on top of other chain, or the bottom of the pot. So it will be 'pushing' (levering around its center of mass) on the bottom of the pot. Since the pot isnt moving down, it must be excerting an equal force up. That is the kick that the bottom of the pot gives the bottom of the chain. Or how the bottom of the chain pushes itself off and 'jumps' after itself.
It would be really interesting to see how friction (like, chain to chain friction) would affect the height or stability of the 'jump curve'. Im thinking the levers might work even better if they cant slide across one-another as easily
This is still such a rich topic for utterly pointless but nevertheless interesting research. How would weight, shape, etc etc of both pot and chain affect things?
Would the jump be higher or lower on mars?

There are three sections to this, a falling chain, a pulled chain, and the curved (top) chain. The curvature begins on either side of the curve at a point where it loses verticality, but snip the curved section off, temporarily. The rising and falling lengths are now the only working parts. Velocity of the chain moving upward is a function of the velocity of the falling chain pulled toward earth, by gravity minus the startup energy required for the non-moving links in the pot. The snap to yank the next ball from dead zero into motion has an energy cost, I'm not calculating that.
Curvature is maintained when equilibrium is attained between a force pushing the chain inward against it's curve, and another one pushing it outward. A loss of this equilibrium would cause the half-circle to collapse or expand until it loses it's well defined shape. This self-balancing between the centrifugal and centripetal forces maintaining a spherical top is a good demonstration of a natural effect.
Ready, startup! When the chain is tossed up and over, the links in the pot are engaged all that remains to shape the curve and maintain it, is acceleration. Objects in motion tend to stay in motion unless it's acted on by an external force, Newton's First Law of Motion.
The curve will obtain a somewhat fixed height according to the properties of the chain, flexibility, the flexibility of the connecting length between chains elements, and without adding much more, the increasing velocity of the pulling (falling) chain. Maximum curve (fountain) height is attained when the velocity of the falling chain is met, at or near terminal velocity, roughly 1.61 meters per second for a small chain falling in air. For my chain, not your chain, I don't know the size of your chain.
For those who tend to think in impossibilities, yes ten tons of chain will probably spin a paddlewheel to rotate a generator...whatever thing. Then there are ten tons of chain on the ground that have to be picked up and taken UP to the roof for a net gain of nothing. So forget it perpetual motion is impossible. Steve you almost convinced me, this demonstration comes around in some forum about every three years. Good presentation! 😂😂😂

Trying to find the 'right' answer, vs. just 'winning'. What a concept. :-)

These were exactly my thoughts on Medhi's video, with regards to his experiments not actually showing the Mould effect. Glad to see them addressed, and with a proper explanation of the wave dynamics!

Two things to help. 1.) When the chain is not moving, it has friction with the surface it's resting on. When you pull it, you break that force of each successive bead, which releases a tiny bit of energy to kick up the bead. 2. The loop gets higher because of the accumulation of successive beads breaking their friction bond with the surface. If you want to see that in action, look at the END of the chain as it leaves the surface. One more thing: The chain follows the path of least resistance as it leaves the surface while accumulating energy from the friction bonds breaking, which is like a very weak rubber band snapping.
Try this experiment in some way where there is no friction and see what happens. Weightless still had friction where the beads met. I suspect if there is no friction, there will be no snap back.

I'm impressed. I had only considered this a nuisance when working with Christmas tree beads. Now, it is something to look forward to trying.
Thanks.

As a kid the "wave whip" with ropes and the like always blew my mind. I would do it with bigger and bigger ropes to see how far it could go.

This explanation really made me see how in Medhi's video every time there was an initial wave imparted, but no fountain grown from no arc

When tension is applied to the chain it behaves more like a cord, closer to a unison body. When it is slack, the *space between links is increased. This space represents unrestrained mobility of the individual link in that space. In the event the individual chain link is pulled on, this should be identified as the transition of character state. The individual links mass, the amount of force applied and the range of mobility of the link determine its trajectory. If the force is great enough it will exceed the speed of cord that has applied the force (momentarily suspending it until reaching its range of motion parameters) The fountain represents directly that a series of the following steps has occurred,
free link having force applied to it,
momentary velocity exceeding that of the the unison body that has applied the force,
submission to the trajectory of unison body by pivotal tension thereby becoming part of the unison body.

British Rail used BRUTEs (British Rail Unitised Trolley Equipment (?). I really liked the way one trolley would follow the one coupled ahead without any inward creep. Did the produce outward creep however?
The best sign I ever saw on the railway was on Platform 4 of Shrewsbury station. It stated ‘No BRUTES Beyond This point’

I'm an ecologist, I took applied maths so I love these but I'm no expert on the physics.
All I can say for sure is: Steve does a mean Clint Eastwood impression during his spaced bead test.

It’s very interesting and fun to see the increasing precision and detail in the descriptions of the phenomenon under study. You can really tell that both Steve and Mehdi are learning and gaining more understanding as this goes on. Good work, both of you!

Love to see you break down the math in a mathematical problem and how you can do that part that gives you the idea on-how to test

I have a counter explanation. As the chain is being pulled from the container the velocity of the chain is ‘throwing’ the mass of the chain upward as that’s it’s initial direction. The balance between the mass of the chain vs it’s velocity is slightly skewed toward mass which causes the upward motion. As the mass per inch decreases I would expect the rise would eventually diminish and eventually start to fall as shown with the chain with the spaced beads.