This String Shooter Is SO Weird

I really want to try a string shooter with variable speed because I think there will be some interesting behaviour at the boundary of instability! Maybe I can modify this one...
You can also discuss this video on REDDIT: stvmld.com/7htxvr_f
The sponsor is KiwiCo: Get your first month free here: kiwico.com/stevemould

I used to think my cat was real stupid for finding such entertainment in a piece of string, but then here I am, wanting to buy one of these.

Bruce Yeany is a treasure. Also I can't believe that opening clip is real. I've wanted a string thing for a while myself. I had forgotten about it.

Hi Steve, thank you for kind words for my video and suggesting my channel This piece has been one of my favorites for years and also one of the most baffling. A far simpler analogy that I like to use to describe the wave movement is somewhat like a throwing a rock in a pond and seeing the waves move out in all directions at the same speed. Now try throwing a rock in a moving stream and the waves moving down stream will move very quickly and the waves going upstream tend to move very slowly. This suggests that at some point where string speed and the wave speed match there would be no wave moving through it. I have a similar piece that produces slow moving waves through hanging string, ribbons, or chains ( 2 videos on this are on my channel) I can easily vary the speed on these pieces and it's much easier to observe the speed of the wave changing as the speed of the chain changes, also fascinating as to how rigid the chain becomes or string on the opposing side. However I have not been able to match the chain speed and wave speed to get a standing wave where I thought it would have. I suspect that as the speed increases the tension increases enough to keep this from occurring (I'll have to get a faster drill and try it again). Another interesting note, is that the string flies due to lift created by drag as it moves through the air (studies have shown this doesn't work in a vacuum). I used to build these and sell them and we noticed that the old worn string fly better than newly made strings. We found that by rubbing new string with sandpaper, little hairs form on the string surface increasing the drag force, thus allowing for longer loops, my longest loop is about 20 feet of string. I do have some additional thought on the string's strange behavior and hope to share more on it in a future video.

Brilliant. But I’ve got all the way to the sponsor read and not a single String Theory gag. I’m not angry, I’m just disappointed.

I'm beginning to think that you just want as many scientific papers as possible to mention a "Mould effect"

We just saw your video! What a great explanation! ZipString on a drill was so cool. Love seeing others use creative ways to solve a problem🔥🔥🔥

Reminds me of the idea of an active support structure like a space fountain or orbital ring. It's particularly interesting that it has such incredible stiffness.

7:29 When the string falls off it looks like a lagged out desynced object in a game!

Steve 'put it on a drill' Mould.

I think you can colour a part of the string so that you can keep track of the string speed compared with the wave speed. Also, I think it would be an interesting wave equation to solve with periodic boundary conditions and setting a moving 0 displacement point where the rollers are.

When you pivot around the handle, the far end of the string has to travel along a much longer arc than the handle does. The string itself isnt rigid so the small force you apply to move the handle a few inches can only move the far end of the string an equal distance in the same amount of time, it takes more time for the far end of the string to complete its arc ater you stop rotating by reacting against your now stationary hand.
When you move in a straight line from left to right the near and far ends of the string are travelling the same distance.
Not sure if thats actually the reason, but it makes sense intuitively. You can also consider how a slack line would behave if you held it in your hand and rotated. The far end of the line would only be moved by an amount equal to the distance your hand travelled.
The more i think about this the more complex it gets. The string is experiencing a centrifugul force thats perpindicular to the rotational force you apply when you rotate the handle, theres gyroscopic procession involved, possibly some sort of mechanical advantage, the role that the speed of the string has on the propogation of waves...

The sideways movement vs turning thing does seem quite gyroscope-y; if it was a solid ring of material that you were rotating in front of you, it would behave like the disc of a gyroscope - resisting its axis being turned, but not resisting movement along its axis. The resistance to turning is, I think, the same thing that manifests the effect of the furthest part appearing to move in unison with the nearest part - if it didn't do that, it would require turning the axis of rotation.
However, I was wrong about the chain fountain thing, so... pinch of salt and all that.

So instead of attaching the sting shooter to a drill, what if you connected it to a speaker and played different tones? What patterns would the tubes impart in the string?

I have so much respect for this TH-cam channel not only does he do informational informative and great content with science. But he also gives full credit where credit is due and that you don't see very much and I appreciate that in a channel

Very cool of you to give Bruce Yeany the credit he deserves! He has inspired so many, as do you, Steve!

im gonna be honest i didnt understand a single thing u said but i watched the whole thing to see u play with the string thing

Being able to vary the roller speed will help explain the wave speed "doppler" effect better. If you could slow it enough and still have a loop, the wave may propagate both ways.

This was really cool. Thank you. I wonder if a heavy rotating belt could support a fairly light gadget on rollers at the top? Maybe you'd need two belts rotating in opposite directions to keep the gadget at the top and twisting might also be an issue.

It looks like the speed/tension work as a parameter in a low pass filter. Reminds me of guitar strings... or rubber bands - if you don't put too much tension the amplitude of vibration is high and the frequency is lower. I also think that the velocity makes that string "tenser" in one axis.

I feel like a stationary one that would plug into the wall and quietly keep a randomly-rotating string in a corner of you living room like a sculpture would be really cool...

Actually, I was taught that this effect and the gyroscope are the same effect, but in the other order. The gyroscope is much easier to onderstand is you first make one from a chain, connected to a hub by a number of strings, a bit like a bicycle wheel. When you try to change the direction of that while it is spinning you see where all the links are trying to go. When you make the system rigid then and integrate over the wheel, you realize that that is where the gyroscope's precession comes from.

That bit at the end with your kid explaining how his new gadget works was so wholesome :') thanks for sharing your random but intriguing knowledge once again!

Just found your channel Steve and it is awesome.
Just pure information and explanation from a kind humble guy, even shouting out other yt channels.
Pleased keep up this good stuff.

A string with a checkered pattern might be interesting for visualizing the waves’ speed relative to the string’s.

When you move side to side you are adding a vector to velocity of the string so the effect propagates at the speed the string is moving. When you rotate you are changing the vector of acceleration of the string which propagates as the new acceleration vector overcomes the inertia of the previous one.

Thank you for the ending! So satisfying!

your channel is pure quality steve, keep it up!

Have you tried moving the shooter quickly towards/away from you? I was thinking that maybe *lateral* motion is fast but linear motion might be different, which might account for the rotational motion effect (a combination of the two).
Additionally, does the time taken to restore the string to the standard location under rotation increase linearly with additional motion? (or alternatively, does the deflection increase linearly with rotation rate) If it's instead superlinear, that would make sense with slower restroation under forward/reverse motion.

Dang. I had a handheld one of these at least 15 years ago my dad found at an airport. Thing was cool

Instantly pre-ordered one. I have ideas for this already. I need a strobe light too. And some glow in the dark string would be cool.

that's why I subscribe to you !
You point out things that every day people see but don't know it.

I think your gyroscope analogy actually really explains it well, where there is momentum stored in the string that resists being distributed. It’s response differs because it’s a competently flexible gyroscope.
I’d be interested to see what happens if you put it on a mechanism that allows it to pivot freely👀I suspect you’ll see a very similar response to a rigid gyroscope

I think the second clip from the end is where you'll find your answer, because there you can see two different types of waves transitioning into each other. I think it's going to be more of the same as what you've already mentioned: the difference between one side being in tension and the other side not, vs coordinate change of the equal tension zone.

You are such a gentleman. I honestly watch your videos and try to incorporate your frank/open approach into my classroom.

It seems to me that we've forgotten to account for the difference between linear displacement and angular displacement when trying to explain the behavior. When you move or rotate the device, you impart a discrete change in velocity to each discrete part of the loop. To simplify things, we will make a few assertions-
1. Our side-to-side movement is at a constant velocity, and our rotation is at a constant rate.
2. Our acceleration is applied in a single discrete unit of time. In other words, the velocity instantly changes from 0 to the final value.
2. The displacement is propagated to all points in the loop quick enough that we will consider it instantaneous.
In the case of linear displacement, the same velocity (in both magnitude and direction) is applied along all parts of the loop. As a result the entire loop moves together with the source (i.e. the device).
In the case of angular displacement, all points along the loop move through arcs of equal length (since we are still applying the same change in linear speed to each point), but arcs farther away from the source radially will sweep through smaller angles, thus causing the loop to appear to curve.
It is also worth noting that there is probably some interesting relationship between the forces that cause the loop the hold its shape, and the torque applied to rotate it about the device. I suspect we could see some interesting phenomenon by tweaking both the rate at which the device "generates" the loop, and the rate at which we rotate it about the device.

Loved the Doppler effects reference for explaining the wave. The beauty of it gets clear when you realise the string is in a loop and basically the handle is “approaching” and “distancing” at the same time towards and away from the wave and that’s why the wave length is different. What makes it interesting is that the amplitude also changes

The difference between the side-to-side steps and the turning really seems to be an agular momentum issue. Something that big moving in a circular path has a lot of angular momentum. Side to side is simply not as much momentum to overcome. Great vid!

This is what I love about the TH-cam science community; the rivalries are entirely friendly in the spirit of discovery, everyone supports each other and promotes great content and genuinely wants every other content creator to succeed and build off of each other, causing all of us to go down this rabbit hole of real science from what started as essentially a school demonstration. Bravo everyone involved

Have never seen one of these String Shooters before. Thanks for sharing.... Now I have to get one.

when I was 10 years old my mother took me to Disney land. The first day she picked one of these string rollers. I played with that thing non-stop for the entire trip. Rolling it all over walls, ceilings, anything I could find. I lost it on that trip and I haved never found a toy more simple and fascinating to play with as a child.

Me looking at the title: oh no, mould effect 2.0?

I would be interested in seeing a scaled up version that can shoot ball chain to see if there is any differences with the extra mass and the more rigid structure.

Bro I've been following him since like 50 followers, this was by far the invention I've been most excited about and now your doing a video about it, thats crazy.

It’s so satisfying to watch Steve getting amazed by a toy, feels like we’re never old enough to stop questioning why stuff happens.
Great video!

The string still has inertia. When you move it sideways, you're moving the whole system in translation, and it is very light so it moves quickly. When you rotate it, it has to change the angular position of the string. It has a moment of inertia, and conservation of angular momentum dictates that the whole string needs to transfer its angular momentum to you and the ground via the device you're holding. It doesn't generate much torque immediately when you twist it so it takes time for the dynamics to propagate.
I know invoking conservation laws doesn't give much insight of the dynamics of the system, but it lets you understand that it has to evolve more slowly given that it's not a rigid body.
Thinking 'out loud' so to speak, the impedance-matching picture isn't a bad analogy. The impedance of the system determines how quickly the wave propagates. For rotation, the wave propagation likely slows down as you go out, because while you're at the center of rotation, an angular change requires a larger displacement as it goes out. When you twist the handle, the system isn't a rigid body. It can't respond with any knowledge of the length of the string (and therefore has no knowledge of the necessary translation at the end)....it just has to propagate outward based on the local tension and velocity until the wave reaches the other end and meets its counterpart.

The behaviour of the waves reminded me of the way the surface of a surf wave smooths out as the wave builds and pitches. Not the same effect, which is simply the surface 'stretching', but eerily reminiscent of the string's behaviour.

When in motion the string is exerting a force (using energy) to leave the loop and the resistance of the string is greater so the loop is maintained in a centrifugal wave a bit like gyroscope but more significantly, like a flywheel. When you move sideways you are maintaining the axis of the flywheel which generates negligible turning force. When you pivot the handle around it’s axis you introduce a new flywheel that opposes the existing flywheel. The time it takes for the pre-existing flywheel to dissipate and catch up with the new flywheel is not instantaneous because the loop is flexible. Since the loop is an affect and the motor is the cause, the affect must fall in line with the direction of the cause and re-establish equilibrium. If the flywheel were fixed like a sold piece of metal, when you pivoted your would experience measurable resistance from the flywheel. The energy of the resistance has to go somewhere and if moved fast enough, tends to want to move upwards... sufficient is the upward force away from the fixed point, that it will overcome gravity.
I think you wave theory is correct btw and is affected by the tension of the string in the flywheel. Like a guitar: the tighter the string, the higher frequency the wave and shorter duration of vibration... String theory lol.

I think we actually *do* see the wave propagating from the top of the string when you move the shooter laterally. The problem is that the wave originates from the shooter itself so unlike when you pluck the top part of the string, the wave is only propagating AWAY from the shooter and moves far too fast to see. In fact, I think what you're interpreting as the string following the shooter when moved laterally, is actually just the propagation of the wave away from the shooter till it hits the vertical "boundary region". Would be interesting to see slow-mo of the shooter being moved laterally to see if we can verify/disprove this hypothesis.

The string shooter should be tested in a vacuum conditions to see how much of air pressure with molecules coming from the roller are affecting the path.

I absolutely live how you take the time to see if anyone else has done a video on a subject and even go the distance to tell us some of the differences between your videos and the others. The way you present the information is really cool makes it amazingly entertaining, have you ever thought about being a teacher?

Yus! Glad for the shoutout to Bruce!

You should make another video on this topic. About the waves. Explaining wave's group velocity and phase velocity in detail. You can also include slowing down of light in this way. Waiting for that.

Looks like I've been enchanted by Steve's big, blue, anime eyes. Mehdi's words had been deeply planted into my mind and I can't get rid of it.

2:43 You can see the wave in the top string, because of the angle of the spring to the camera compressing the appearent wavelength, it stands out.

I definitely saw the wave in the top string mentioned around 11:40. The key is that the wavelength is far longer than the string, so all you can see is a small part of the waveform at any given instant. If you pause the video during the side to side perturbation, you can clearly see the curvature of the string that is indicative of a wave. If you could capture the discrete coordinates of the string along the top of the curvature, you could do a discrete Fourier transform on it and that would give you the frequency of the Doppler shifted hand movement. After accounting for the Doppler shift, the frequency of your hand movement would be the primary frequency remaining.

As for why the string looks like it doesn't have waves when moving side to side, I think I may have an explanation:
When you pluck a string on the top part the one coming to you is slowed enough that it start going away from you. However when you move side to side, the origin of that movement is at the string shooter's rollers. So that wave still exists it just goes down the string fighting against the speed (higher tension at the rollers give it the boost to not go up), meanwhile the part of the wave that goes with the string just goes around so fast you don't see it.
I also think you might be wrong about the turning, it's not that you impart a wave on top and bottom at the same time, that still works just like translation.
I think it is essentially the gyro effec of the string, and the reason you don't see any procession, is because you're holding onto the string shooter.
I think what's happening is that you have the linear momentum of the string coming out of the shooter trying to fight the angular momentum of the entire string, and as you keep adding linear and angular momentum on one end, and rooting yourself to the world so you don't counter-spin eventually the angular/linear momentum from the string shooter wins.
Still I wonder if when you turn if the string rolls along its movement axis, would make sense to me as that's yet another way of preserving the original angular momentum.

I'm thinking that this analysis would benefit a lot from slow-motion footage! Also, I love the mesmerizing images from the double spinning demos.

Something about him lying on the ground and watching the wave spin makes me so happy about the love he has for the beauty of the laws of physics.

its been really interesting watching this series, you could have taken it step further and used integral calculation on the string to go deeper into why it behaves like that
looking forward to seeing what you do next

Wave speed on a string is sqrt(T/mu) and the chain's tension varies with height; so exactly what point in the chain is the chain speed equal to the wave speed? In fact, the tension in a vertically dropped chain (suspended from one end and dropped) is zero if you neglect earth's tidal force. Immediately after the rollers the tension approaches zero -- possibly is negative for some circumstances -- in which case wave speed is zero (or possibly imaginary and dissipative); thus no wave propagates. Applying friction to the top of the loop increases tension after the touch and greatly increases wave speed... the wave is then reflected by the rollers and the reflection is inverted. The string motion is the sum of these two waves.

Some of this would be easier to communicate if, instead of saying the top and bottom string, you called them the departing and returning parts of the string. A dark mark on the string would also make the movement of the string more clear

I’m glad you decided to stay on here and making videos.

Amazing! Preordered 2 of them 😇

8:10 And "they" said: *"yOu cAn'T pUsH a StRiNg!"* and here is proof of how wrong they were! :D

I have questions.
Have you tried to rotate the strinthing, so that up goes down ?
Could you manage to build this into a device, with a very, very long string?
What would happen to the wave?

I had one in the early 2000s from Spencer’s that had rainbow string and was handheld. It made awesome colors when they blended

Fun stuff. Glad I found this channel! 🤘

I think it would be incredibly useful to dye a bit of the string so that we could easily see the direction that the string is moving. It's not easy to tell, and I keep getting confused about what direction it's spinning.

When you attached it to thd drill, the helix shape was pretty interesting. The frequency in the z direction of the outside string is far less than the frequency of the inner string.

the doppler effect explication was really helpful

So much integrity and honesty 👍🤩😍❤️❤️

My first reaction when I saw this was "oh no, it's another Mould effect".

Lol, "and here we have a wild mould in his natural habitat, playing with his effects"

I had a few of these as a kid, we modified 2 of them to combine em and spin a double size string and also play with it as a jump rope

Fascinating! The trajectory of the rotating string shooter looks similar to that of some strange attractors - particularly the Sprott attractor which has a central rather tight spiral and returns via wider loops around the outside. Coincidence???

I love the faces Steve makes when he's testing stuff like "wtf is going on here"

Just gonna keep milkin that chain fountain, eh Mr. Mould Effect?

Yup, definitely preordering this.

This reminds me of electricity, quiescent draw, instrument amplification, and signal-driven changes in impedance against a coil. The speed of the string is a "voltage", the energy of the moving mass is kind of like a big battery/capacitor/filtering network, and there's a "quiescent draw" against that constant charging of the system like a bias against a tube passing current, which I think is a result of exterior forces imposed onto the system (friction and gravity). Your impressions onto the string and the movements/axis accelerations of the shooter/spinner would be changes in the control grid voltage of either a triode or pentode, and the behaviour of the string demonstrates changes in impedance.
The simpler demonstration is in just touching the top or bottom of the string as it moves along. This is most like a triode, in my opinion. I like to see this like resolving the signal path and draw characteristics on a circuit. When tapping from the edge of spinner's top, you can see the effect/signal amplify at the "peak impedance point" for a moment. If you keep your finger in place, you've create a new bias/impedance point; and if you waggle it, we can see an amplified waveform. Plus, we can see the draw can be seen/felt at the returning edge at the bottom of the spinner. When tapping it from the bottom, I think this is what might me a "cathode follower" in tube circuits. I think the bottom taps and friction slows the string down, and drags the whole system down (increasing the system's impedance), like adding a resistor to restrict cathode flow, affecting the global bias point.
Not to get super nerdy about it, but this "cathode follower" design is a common low-impedance drive circuit in tube amps, and is known for smoother overdrive characteristics. Tapping from the top is maybe like a later Fender design (AA864 circuits) which sound a little harsher and blockier, exaggerated even when overdriven. When you tap the outside edge (where impedance is greatest), it's more like a microphone, or, your finger effectively turns into a resistor/capacitor, eating some voltage/speed, feeling current/heat on your finger, and ability to sense other waves travelling through the system in the form of reductions and increases in voltage/speed and friction/current/heat.
The less obvious/probably incorrect effect I'm seeing here is in the side-to-side motion. I feel this looks like pentode behaviour, where the voltage is held more constant (we're not messing with the spinner's Y-axis), and we're applying a considerable X-axis. Watching it be resolved, I want to say there's a smaller drop in speed/voltage/Y-axis energy for a considerably larger distance travelled across the X-axis, and the system resolves the energy on the X-axis as if it were "capacitively" more efficient as a result of your arm become a part of the impedance network. Which is a mixed blessing. Smaller forces might not require any extra input from your arm to control the system gently. Just as well, too strong a swing would overwhelm beyond reasonable correction, and your string turns into a whip (this is when vacuum tubes arc).
Also, when you're rotating the string-spitter with a drill on your back, I think this is maybe a "visual" of a parasitic oscillation. With guitar amplifiers especially, it's sometimes possible to produce a high-pitch parasitic ring with too much high frequency bypass. It's also possible to produce oscillating hums with over-filtered or poorly arranged power filtering schemes (usually an inaudible low 4-Hz up and down drift that shows up on the speaker output).

I had one of those toys as a kid. It had flashing lights and played music too! I loved it until my friend "borrowed" it and I never saw it again sadge 😔

You already have a Mould Effect named after you. Once you figure this one out, you can't have another Mould Effect. Unless, this is an extension of the same physics, which would be interesting.

Your mind is an incredible inspiration. Thanks for such cool content.

This in new to me... Amazing!!! I totally need to try this!!!

The real string theory

I think you made an incorrect assumption that the tension in the top of the string is lower. The device is NOT the only source of tension here! The tension along the length of the string travels at high speed (maybe a hundred miles an hour or something), the weight (and momentum) of the string itself creates tension. The bottom is actually at LOWER tension. And that's why you can see the waves. The waves at the top go too FAST, and are likely being damped out by the air and the string itself, as well as being carried along with the motion, at the bottom they are somewhat under-damped, and move much more slowly.
The rotation effect is basically gyroscopic-but there's no strong bearing. If you look at the string entering the device, it lags, and it leaves leading. That's the device creating the precession. Note that the loop is angled to the vertical, that's the wobbly string version of precession.

I think that the top string is being compressed along the length as it is being pushed outward at high speed, making it act more like a solid stream , as the tension release going towards the bottom part you end up with slightly looser string closer to the end of the loop which allows it to have more flexibility and allow to bend a lot more.

I just got mine in the mail today. It's really fun!

I saw this item on a french channel. The man spoke about chain fountain as well. But he didn't mention the "Steve Mould effect". Which was disappointing.

Im just curious if a cat can play with it. Can you imagine the hours of bonding you would have with your cat over string? Top comment has a point lol

When I first saw these, I instantly thought of you Steve :D was waiting for this video!

I ordered a Zipstring in the US on November 21, 2021 and it FINALLY arrived today! It is lots of fun.

I've never seen a youtube video say uploaded 20 seconds ago, cool

Jes🙌, I've massaged you on Instagram about this and i already know it's gonna be such a cool video

yessss the day I've been wanting for is for you to react on this

Man, that is simple but the visual effect is so cool. I can see something similar being used in art installations...

Your question towards the end, I think you already explained earlier in the video. You can't get a visible transverse wave on the top part when you move the handle laterally, because the wave _initiates_ at the wheel. Waves in the top part only propagate towards the wheel.
(or more precisely, you won't have a significant fraction of a cycle of even a single wave present, so it looks like a straight line)

my uncle had a string thing growing up and he had another one that seemed off brand that had led lights that lit up the string colors it was awesome

Top wavelength is slower then you can see, but it is there with the side to side. Its more apparent on the drill where you can see 2 twisting waves as spirals, with a long (top) and short (bottom) wavelength.

if you look from the top as you rotate the string shooter you see that arc that you would see in the chain fountain, changing the direction effectively makes a chain fountain, so whatever forces govern the string fountain also causes the string to twist in the way it does.