Trying To Solve The 150 Year Old Mystery

Kind of amazing that they know how to detect the Higgs boson, but do not know how this basic device works.

I used to have one of these as a kid. I always assumed the light heated the black side better, which heated the air causing a small local pressure increase, which pushed it. I had no idea there was so much to consider and that it had stumped some of the greats. Thanks. :)

The non-spin of the holes is a result that seems like it's worth pursuing. If you know why that stops it spinning, you might know why it spins without them.

Here's something else to try. Replace the squares with disc's where the center is white and the outer ring is black. Hold the size of the center constant while varying the surface area of the outer black ring. Record results.
Swap the white and black parts and repeat. Record the results and compare.

It would be interesting to try vanes with vanta black and the whitest white to see if that has any effect.

In 1968 or 9, I was 10, and the teacher showed us one of these. Then we read in the science book about how it worked because of the photon pressure. "Interesting," I thought. I looked back at the radiometer. It was spinning the wrong way. I raised my hand. This observation resulted in an argument and me in the principal's office. I couldn't believe I was the first to notice it spins the wrong way.😉

“Every tool is a hammer, except screwdrivers. Those are chisels…”
I’ll add files to that category as well 😂

You need to make sure the rotational momentum & CG are the same between the ones with slits/holes punched/solid, i.e. if you punch holes you will need to make the paper longer, and if you cut slits you will have to stack them horizontally.
Also, the hole punched might not work because it might caused local circulations and negated the effect but that's just a guess.

You might be on to something with the laser. Maybe try making both sides dark but have 2-3 lasers set up around it that only hit one side of each vane as they turn.
It could also be interesting to design two radiometers with a layer of material between the two sides of each vane. Make one where the material has high thermal conductivity, then another where it has low thermal conductivity. See if that has any effect on the speed of rotation. Maybe do this again but also with the first suggestion, making both sides black and aiming lasers so they only shine on one side of each vane.
And on top of all of this, vary the vacuum pressure within the chamber to look for any sweet spots for maximum speed.

I wonder if you could use Schlieren imaging to observe the air movement that the hypothesis proposes

Great experiment on the Crookes Radiometer! You might find the 'orbital repulsion force theory' intriguing. This theory suggests that when electrons in the vanes' material absorb light, they jump to higher orbitals, momentarily increasing the molecule's size and creating a repulsive force between adjacent molecules. This force could be what drives the vanes' rotation, rather than just air pressure differences due to heat.
To explore this theory in your experiments, you could focus on observing how different light intensities or wavelengths impact the rotation speed. Since electron orbital changes depend on energy absorption, varying light properties might yield different rotational behaviors. This could provide insights into whether the rotation is driven more by molecular-level quantum changes than by macroscopic thermal effects. Love the channel ❤

Is there a list on physics problems like this that don't _seem_ too hard to solve, but do?

Add a tiny serrated edge around the perimeter of the squares... this will increase the edge path length... punching holes and cutting into small sheets decreases surface area and hence speed

3:40 Betterhelp is asking for trolling if they allow text. I can imagine someone automating Chatgpt to be on the other side.

when studing engineering I tried to make a Crooks' radiometer with tiny slim magnets as vanes, in order to generate electricity on a coil... it was a huge failure lol, it cost me one semester... but I learned to work with molten glass, which was cool.

These light mills work on air molecules. Too much air in the chamber and the light makes the molecules bounce off of each other creating a neutralizing effect. Too little air in the chamber and nothing happens. With just the right amount of air, the molecules bounce off of the black side where they receive more energy since the black side is hotter than the white. The white side reflects more light keeping it cooler. The radiation forces from the reflected light is not enough to cause movement. That's why it spins away from the black side.

My guess:
At the surface, diabatic heating will transfer energy to the air molecules in very close proximity to the vane, imparting kinetic energy to them. Due to there only being 180° of a cone those molecules can travel due to the vane being in the way, an equal and opposite reaction occurs. The molecules transfer some of their kinetic energy into the vane, moving it in the opposite direction as the molecules lose that kinetic energy and cool to a lower temperature.
I guess there will also be some complex vortex physics going on at the same time caused by the vanes spinning around and displacing the air - something I don't know much about.

the guys at the action lab are the kind of people who can solve a 150 year old puzzle

I have seen in another video that the rotation depends on light color : with one monochromatic led light it turns and with another LED with another color it doesn't turn even if you augment its intensity.

Love your videos, man!

I liked this new format of the video. Good luck, keep it up.❤

If the action/force might be acting on the outside perimeter, I wonder if making the edge notched would have an effect. What if you cut zig zags on the outside?

Thanks for the video.
It seems really important for science to be able to explain things like this. It makes it obvious that we have gaps in our understanding.

Fascinating! I say it calls for more experimentation! Is there a way to get higher vacuum? See how different levels affect it? If it's a heating effect, why does a small light of the right wavelength have more effect than a powerful white light? Does violet or ultraviolet produce that much more heating?

It feels like holding the laser in place and letting successive black tiles pass in front of the beam would work better. Also try 2 beams- one on the white and one on the black.

i recall one of these in my science class when i was younger. It sat on the window sill and when the sun hit it - it would spin very fast. I was sure it was the heat given off of the black side that made it spin; as like a black car and a white car in the sun. the heat may create energy or change the structure of one side of the metal. Try with plastic or even circles. great video.

actual science in the making. good on you for trying these different things to see if there is an effect. would have liked to see you shine the laser on the white parts also.

It didn't know this was still a mystery of sorts. That explains why I always have this puzzlement when seeing this device, having heard various different explanations for how it is claimed to work. So thanks! I'll take a mystery over an ambiguous claim any day!

The volume in the small vacuum is different, thus the delta needed in a bigger space would be more. If the space were minimized in some way, to the same volume within the bulb, that could maybe work better?

AIr molecules meeting hot/fast molecules of radiometer have higher momentum after impact with hot/fast molecules of radiometer. In law of conservation of momentum radiometer fins have opposite rotating momentum. It works only in low pressure because viscocity of air increasing (with pressure increasing) faster than momentum. And in atmospheric pressure viscocity of air is too high (air resistance too high) for any rotation. Also may be at higher pressure free path of molecules can be too small to take hot/fast molecues far from fins.

My guess is it's the expansion of the heat off the surface that then pushes the surface away. As the material would have a heat resistance above that of the vacuum, the easiest path of the energy/heat to go is away from the material thus pushing the material away.

You could also use a high speed camera (The Slow Mo Guys / SmartEveryDay) to figure out the thermal circulation works within the device. Both channels have done something like this in other contexts, but I hope it would work here also. Maybe a collaboration between your channels of some sort.

Black surface absorb more energy than white. This cause the air directly in contact with the black face to be cooler than white. The air pressure is higher on the black side, pushing it foward. The delta pressure is so tiny that the contraption needs a low vaccum to overcome the drag force.
Punching holes cause air to move through, highly reducing the push force that becomes less than the drag force needed to start the spin.
Increasing the surface, by cutting in half the faces, increased the drag force, thus reducing the speed.

Explanation is very simple. Dark side works as a piston. It locally warms up the gas, that is accelerated after contact with surface. But you need to use particle model in your mind. Free path in low vacuum has to be big enough. This way "hot" faster particles have a chance to escape far from surface before thermalization, and there is no isolating layer having gradients of temperature close to black surface. The device works in the regime where gas can not be considered the fluid (ideal gas).
In the statistical sense all you need is to have a lot of cool gas particles that hit hotter surface. Hot particles can create backpressure, but it will be smeared and that pressure will also act on silver sufaces. Additionally most of the cooling will happen on the surrounding glass surface. So the colder glass is, the more efficient "engine" will be. Gas inside bulb is not thermalized - distribution will be a sum of few almost thermal populations with distinct histories of the last contact. There will be black populations, silver populations, side populations. The longer history history you will consider as population division, the more thermalized subpopulation you will have. For example: Glass-Glass, Glass-Black, Black->Glass, Black-Particle, Particle-Particle,
Mechanism of the force generation starts in the exactly same time when most of the drag components dissaper, so that correlation could be additional difficulty for researchers because it coud hide the true nature of phenomenon.
Holes obviously won't help.
(PS. I was smarter than Einstein - just in my own way ;) )

When you tried it in the vacuum chamber, there was no globe. Maybe the globe is important because of the way the air swirls around the inside.

It actually won't spin in a complete vacuum, so you were low but not zero.

Really interesting, didn't know about this before

I do not know how it works exactly but it sure is an elegant looking device and one I like seeing.

Try Infrared. (Need a material allowing it to pass through though) Wire the IR emitter onto the inside?
Ultraviolet.
X-rays.
Gamma rays, lol
Stuff other than completely visible light.

The whirl of the cooling fans on that flash light are insane lol

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I think the light bounces many times forward and backward in case of dark material and it sums to less Newtons in one direction. In ideal case the light bounces once on the lighter material

Would've liked this to be a little more scientific. Theres a ton of potential errors. Next time maybe mount the light sources and get better measuring equipment for the vacuum.

Thanks. If I were trying to solve this, I'd have otherwise identical radiometers, & only change certain configurations: colors, holes, etc. Put them all side by side in the same light source, & see what they do. Just manually shining a laser on it is iffy because you're trying to follow it around with your hand motions, which can't be standardized, & therefore represent an uncontrolled variable. tavi.

you can combine this experiment with the ionic thrust, both use the same principle, one creates a thermal vacuum, by giving energy to air molecules that is bein replaced by sorrounding, low vacuum air, and the other an ionic vacuum, ionizing air molecules that are repelled and the vacuum filled with sorrounding neutral air molecules, If you can coat the plates of the radiometer with a thin electrical conductive layer of metal and plug it to HV you should see the same. Eventually you may see opposite rotation, depending on the metal coated surface.

that rotation measuring by heating parts of the tiles felt sooo scientifically accurate x)

I am a Commerce graduate and yet I am here just to listen to this guy.

you should check into the reflective and absorbative properties of each material for light and heat. would not hurt to know the electromagnetic charges and specs on them too. i. e. one black ink may act as an insulator whereas another may have heat resistance...

1. I recommend putting a control top in the same vacuum box you are using as the vacuum might be different
2. Try different gases: Helium, Argon, CO2 to see if the residue gas mass has an impact on the speed.
3. Instead of black use a color paint. & use a light source that is reflected (ie same as paint color) & a different light source that gets absorbed.
4. Try a cone shape blade & do two tests, reversing the color of the sides. The cone shape would like impact the direction the gas molecules.
5. Try different materials. For instance a metal versus glass\mica which has an low thermal transfer coefficient.

You missed the part where 'better help' sell their customers sensitive data to zuckerberg

My best guess is thermal expansion? And it has to be in a vacuum because the force exerted by the expanding air wouldn't be enough to overcome air friction? The problem would be that with less air inside to slow down the vanes, there would also be less air to expand.
It definitely seemed like the total surface area had a noticeable effect. Maybe that's why it wouldn't move after you punched holes in it?

How about trying the experiment with different internal air temperature? What about tiny needle-punched holes instead of big ones? How about perforating the edges so they have longer length while keeping surface area near identical? What about using long thin rectangular strips instead of squares? What about different "blacks", for example Black 2.0 or Vantablack?

Are you sure the cuts and movement of material didn't shift the center of mass and add some friction? It looks slightly tilted.

Omg I saw you today at Disney, I was so shocked to see you and wanted your autograph so bad! We gave you six small cups!! It was great to see you!

Make one with vanes that have a spiral cut groove through the whole thing. You'd have a massive surface to edge ratio. Also, when you cut the vanes down the middle, you greatly increased their moment of inertia by opening them up so wide, of course it didn't spin much faster.

Have you ever tried imparting a Dark Plasma to the chamber? It would be interesting to have a sub luminescent voltage applied to the chamber once evacuated then test the light interaction. Then fully ionize the the chamber to impart an intrinsic glow then apply laser to edge....... If you flood with Xenon then evacuate with some ionizing source like a bit of Americanium from a smoke detector it would make for an interesting experiment. Thank you for all you do to bring physics to understandable elegant application. Cheers

I always thought it was a matter of heat difference.
The black side heats up more, thus heating the air close to it.
This air then expands and pushes the disc.
In low density air (low pressure) there is low friction and also relatively more pressure difference for the air heating up and it can't transfer heat to other air molecules very efficiently.

It would be interesting to look at a radiometer with different scarce gases inside. Argon vs water for instance to see if polar molecules behave differently.

The coefficient of thermal expansion may make a difference. Eg. Neon will effect greater thermal expansion than if helium were used. Differential in speed noted if variance in RPM with different noble gas would impart support for hypothesis. If movement is due to electrical force, delta of milieu voltage will elucidate that.

You appear to have forgotten about the increase in radial inertia required to rotate the veins after splitting them, Yes you increased the surface area, but you also moved half of the area further from the centre of rotation

I wonder if flushing the chamber with different types of gasses before creating the vacuum would have an effect. Maybe sulfurhexaflourid ? Maybe cold Helium ? ( just extending some other comment idea where the conservation of momentum would be the reason of rotation )

If you can find a way to measure the force imparted more exactly, this might be far easier to work out.
Maybe a single blade of the radiometer in a vacuum, hit by a fixed laser, to measure how many degrees it rotates off whatever force it gets before rotating out of the laser's light? That would make tests more reliable, so simpler tests could be performed like the light position you did, or seeing if light angles matter.

well, I think what happened was when u heated the era up air molecules pumped to the area and got accelerated away and causing an opposite force on the thing. and it doesn't have to do with corners, and this makes sense because when u cut it u didn't change the area, so it was spinning fine but when u punched holes and reduce the surface area it didn't work.

Add a tiny serrated edge around the perimeter of the black squares only

It seems like a form of a "Solar sail" Where the photons are able to interact with the black parts of the material. Which could induce a slight force that's maybe causing temperature or pressure changes in the chamber

The light heats the black side and in turn heats the thin air next to the black side more than the white side, thus the expansion of the thin air on the black side pushes against it in the contained area. If the air is thicker the friction of the air molecules and density prevents the push force from being enough to turn and "wind" the air movement enough to allow spin.
So it is merely heating thin air molecules off the black surface which expand and thus "push" the black side.

I think the moment of inertia does play the role here - how fast you can reach top speed of rotation. For each point I = m * R ^2, but power advantage is proportional to R, so R / R^2 = 1 / R; the same mass and square should accelerate to max speed faster if they closely distributed to center. So cutting with /\/\/\ shape and moving closer will help until it reaches the max speed, which is limited by friction on top. I think drop of lubricant / type of lubricant / how much or lubricant is used (to not create more friction in edge case) is what can make difference.

I own one of these. After playing with it, I noticed something interesting: Moving it, touching it, bumping the table or any source of vibration will cause it to spin, sometimes quite rapidly, and that it only ever rotated one direction.
This leads me to believe there is some etching in the cusp of the glass, where the tip of the metal sits, that prevents back rotation. Or said differently: it allows it to only turn one way. It functions as sort of ratcheting mechanism, that prevents backwards progress.
In this way, it essentially translates random motion or vibrations or an oscillatory motion--any of these--into forward-only rotation.
This doesn't fully explain the radiometer, but it requires less special or magical behavior from the vanes: It doesn't matter if the forces on the vane, each direction, ultimately cancel out or are symmetric. So long as the forces happen at slightly different time offsets, or is oscillatory, then it will rotate in the forwards direction.

Considering that most of our frame of reference and intuition in science is based on what we've seen and experienced on Terra/earth, with x num of heavy particles, X gravity, X air pressure and so on, I'd put my money on the notion we're still missing something here. Air pressure changes all kinds of things with elements, crystallization, and has to have a cascading effect across other metrics as well. It only stands to reason. Most of our inputs are fixed, and also fixed inside of pretty small ranges even with what we can change kuz money is also a factor. This was a fantastic video! kudos!

Would be interesting to attack the laser to the assembly and see if it continues to accelerate in that configuration. Maybe if it is too heavy, something like a fibre optic cable to reroute the light as the device spins would be interesting

Hi james, at atmospheric pressure, can the radiometer spin because of infrared radiation instead of white light? Also did you try pointing the laser on the white surface?

I'd like to test different conce tration of gasses. Superlow vacuum but made out of co2, he, ne, etc... And see how much it would affect.
My feeling is that denser gasses will make it spin faster. I think the vanes are thermally vibrating and any random molecule that impacts on them, bounces off, mechanically imparting a reaction force, not due to "higher pressure"

Assuming the black side is hotter or imparts heat to the gas molecules that bounce off it. Ie to they depart with a higher velocity and impart a small velocity to the vane. Once the vane is moving it transfers some of its extra velocity to the molecules striking the cooler white side until an equilibrium is reached. The equalibrium result is the spin speed it dependent on the sustainable temperature differential.

I wonder what you would see using schlieren photography, would it show the air moving away from the hot side? Might help to visualize the forces.

Interesting. Cutting the vanes may have reduced the temperature on the black side and hence reduced the temperature gradient, which is the main driving force. We have so many physic models that can simulate the outcome of many experimental results with high certainty but not so much on this old science toy. Here is another paper on Crooke and Hettner radiometer DOI: 10.1088/1361-6552/ac420b

Try conical, black inside, white outside. I think that will work like a propeller

Point the laser at the inner and outer corners instead of top and bottom corners - you may be getting a lever arm from the center to the point of heating and may get a bigger speed difference that way.

5:57 Isn't it possible that as you cut those slits, it moved the overall geometry further away from the axis of rotation and due to conservation of angular momentum, it spins at a slower rate as a result. Given its size, I'd say even a few mm would make that difference and with your results, that variation might match up

Is there a way to create a gradient of heat absorption to test out thermal transpiration?

maybe the paper squares are vibrating at high freq. like little drums - would explain why it doesn't work with the middle cut out

It may rotate by heating the tiny air layer over the wings, at higher temperatures on the dark side.
In absolute vacuum this wont happen, and possibly at 1 atm pressure air drag overcomes the effect or even heat dispersion occurs at ratios that allows pushing on all sides.
This could explain why it doesn’t turn with holes, by decreasing heated surface.
One way to prove it may be building another model with one face of each wing heated by Joule effect with direct current, for example

Does the wave length of the light matter?
How does the force evolve with the light intensity?
Are there electrical charges accumulating somewhere?
Is it the same in a magnetic field?
Does the distance between the glass of the bulb and the rotating thing matter?
Does the angle between the light beam and the surface of the rotating thing matter?

What about a material with different thermal conductivity? Or making the squares bigger?

It would be a magnetic effect that would normally get ruined by the air around it? Try other gasses with specific electric properties instead of a vaccum and see if that can be graphed to show predictable speed changes. Modest and low densities of each.

It's the same unknown side force you get when you shake sand up and down with a speaker at certain frequency. The speaker moves up and down, the sand moves up and down but an unknown side force acts to push the sand into lovely patterns. I think you should do a video about this.

I wish you had tried to spin it with some infrared source. I mean, it must react differently to different wavelength and energy levels of lights if the reason is thermal transpiration. It must spin faster with IR light. And I think it maybe spin slower under the ultraviolet light even if UV has the most photon energy in our visible spectrum. Because as far as I know the best wavelength to transfer energy as heat is infrared despite UV has the most energy.
I mean, if the reason is heat, IR will perform better, but if the reason is photonic pressure caused by momentum of photons, UV will perform better. And i think this experiment would bring us a solid answer about the question.

I was always curious if the slight pressure the white vane gets tilts the apparatus on the pin inside the hub, and the hub slides back down that tiny amount on the pin, creating rotation.
I saw that the hub wobbles when the radiometer turns. Part of how it works?

Have you made the two rotating foam cups with strips of plastic trash bags that are brown on one side and black on the other?

I read somewhere that there is a sweet spot in the air pressure in the tube. If this is true It would be interesting to see what a fine mesh would do (painted white and black)

In your experiments you do not maintain a constant angular distribution of mas. Like an ice skater spinning faster when they bring in their arms. I think measuring rotation frequency is a reasonable approach, but you may want to place a mirror attached to thin wire and measure how much it twists using a reflected laser the amplify small rotations. Also a way of measuring the force of gravity between two suspected objects.

Try aluminum foil vanes with those fancy black and white paints you were experimenting with before. Try a frequency of light that isn't absorbed by the atmosphere and the clear cover over the vanes. Ooh, try that camera trick to see air currents where you shine a point light source at the edge of an object. That last one might be hard since the blades would clip in and out of the focal point, but maybe with a high speed camera and frame rate tricks something awesome would show up?

could be interesting to try making that squares shape look like tiny bowls

I had one of these as a kid, put it in the sun, and added several mirrors - man, did it spin fast, Added a concave shaving mirror. The best! Got a small puff of gas and it never worked again.

Obviously, what makes them spin is a 90° corners, where the turbulence created. Cut more 90° corners shaped stars ✸ to make it twist faster.

According to (German) Wikipedia the (obsolete) "edges" explanation is from 1879. As far as I understand nowadays it is considered that the bouncing molecules on the surface are the driving force. That's why a reduction of surface area by punching holes results in no movement, and why producing more edges do nothing.

Use some black 4.0 on the dark side and something more reflective on the bright side. If there is any changes it could help identify some characteristics that will lead to the answer.

Keep playing! I would like to know if different wavelengths affect the speed

My guess is that the black side becomes hotter than the white side, and air molecules hitting the black side get more energy and more speed as they bounce off, imparting greater force on the black side and spinning the vanes. Basically, the hotter molecules on the black surfaces kick away the air molecules with greater force, thus producing a greater reaction force and making the device spin.

Cutting two wholes in each piece of paper reminds of the wave vs particle experiments.

Try to focus the laser in one line of sight to have all wings be touch by the laser, this will rotate it faster compared in focusing in one wing.
Then try to do the same while shining the edge or the outer left corner of the wing, you will see it will rotate faster.
Try to time at least 2-3 cycles to get a much better time difference.
After doing the steps above, you will see that its definitely, not Thermal Transpiration.