The Mysterious Entropic Force

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So all I have to do is spin my room?!

I'm a physics student, and to my limited knowledge, the entropy of the dice did decrease.
But the process still happened because of the release of potential energy when a die falls.
The spontaneity may be determined by the change in the Gibbs free energy, which is given by dG = dQ - TdS (assuming isothermal and isobaric process). If dG < 0, the process is spontaneous.
This is because the increase of entropy of the surrounding (-dQ/T) compensates for the decrease of entropy of the system (dS), thus abiding by the second law of thermodynamics.
In this particular case presented in the video, since the system is not isolated (meaning, work and heat can trespass the boundary of the system), the decrease of entropy of the dice is compensated by the increase of entropy of surrounding caused by the release of heat that generated by the falling of the dice.
I genuinely enjoy every video of yours! Thanks for uploading such an amazing video :)

Another thing to consider
The dice and nails also reached a state where the gravitational potential energy of the system was minimized, the disordered arrangement took up more volume meaning there were lower states the dice could be in if organized.
The gravitational potential energy was thus, dissipated as sound and heat.
This is equivalent to the nature of living systems. They exist in what we would call a more ordered state, but their capacity for converting useful forms of energy to waste heat more than offsets any apparent decrease in any other aspect of entropy they cause.

Gotta disagree with the reasoning that there is more entropy in the ordered dice because they are more compact and "have more room to move around." They only have more room compared to the height of the disordered state. The dice are not actually concerned about the height of the disordered state, so I would argue that they are in fact at lower entropy since the room they care about (to the sides and below them due to gravity), is less, and there are fewer opportunities for the dice to move around.

Does entropy also explain why elementary school students never line up in a straight line?

2:35 sounds fishy... please check:
1. microstates in the Bolzmann formula have the same energy. Here, if any dice goes to the free space above, the system will have its energy increased by the work against gravity. This breaks the condition of the microcanonical ensemble
2. Microstates are equally possible, however we don't see dices jump into the free space by their own will, therefore the shown state has much larger probability to be in and this breaks the condition of the microcanonical ensemble

I think if whoever the first person to use the word "disordered" to dscribe entropy had instead used "homogenous" or something I think we'd be like 50 years ahead with our understanding of physics and information theory

Excellent video, but I think you have it wrong with regard to the dice and nails. They settle when jostled into the lowest energy state - that being the lowest overall point in the gravitational field they are in. Do the same thing in a location without gravity and you'll get different results.
I agree with the rubber band example however. Note that stretching a rubber band heats up the rubber, and it cools again when it contracts. This is consistent with entropy. The nails and dice would also heat up (or increase in average speed) if you jostled them in zero gravity just like the rubber by the amount of energy expended to jostle/stretch.
Entropy is simply a measure of how likely a configuration is. Sure, it's possible that rubber band could stretch itself just sitting on my desk, but with 100's of billions of molecules in it all needing to do essentially the same thing at the same time over a long period of time (contextually speaking) a mathematician would call it a statistical impossibility.

This is a wrong explanation.
The spontaneous orderly arrangement in the example is due to the effect of gravity. Dice can lower their overall center of gravity when arranged neatly, and the same is true for nails. If gravity is removed, such as by astronauts conducting experiments in the space station, you will see that neither the dice nor the nails will spontaneously organize neatly.

Now try the same experiment without gravity pulling all items into the same direction.

'Amount of free volume per dice increases'. I thought that the amount of free volume is the same before and after aligning dice in a finite system, it is just that the same 'old' free volume is now concentrated in 'new' free volume in space continuously, above the dice, not scattered between dice.

0:10 As ITALIAN i recognise the “why”😂

They all align expect for that CHAD nail at the bottom 0:57 seconds

3:33 This is semantically untrue. The reason the rubber band returns to an unstretched state is because of electrostatic attraction and repulsion between the molecules within the rubber, which respectively resist stretching and compression, and thus effectively function as an elastic force. You can explain this as a mechanism that acts to increase entropy, but this does not change the fact that the force is elastic in nature.

Ah entropy, the 3rd wheel of thermodynamics

2:54 would have been a good idea to start the video with “entropy is defined as”

To my understanding entropy describes particles "desire" to reduce their energy to reach the most stable state. The dice prefer the tightly packed state because here they have the lowest amount of potential energy. Also it takes a lot more energy to break that state apart, because the previous unorganized state could be broken apart by the tapping / rotating, the new state however is hardly affected by it.

The trick here is not to compare the original disordered dice configuration to the final ordered one, but rather to imagine the distribution of dice orientations while the container is being shaken. At equilibrium, most of the dice align and the ones near the top are constantly and rapidly bouncing around.
If the container is not being shaken, the entropy of both configurations near zero because the dice have almost no probability of changing state. And analyzing the situation becomes harder because the disordered configuration will have a higher energy level due to potential energy than the ordered configuration

All those squares make a circle ... all those squares make a circle ... all those squares make a circle. ..

The ordered jar has less entropy, with the dice compacted there is less positions they can actually occupy while still looking the same in buik; but the total entropy of the Universe increased with the heat of the friction and collisions though. Just like life, we may seem to violate the laws of thermodynamics with all our growing and reproducing, but it's actually the opposite, we spread heat more easily than still rocks.

I feel like I've been brainwashed

Reminds me of how the initial state of the early universe would have appeared about as random/disordered as possible yet gravitationally speaking was very low entropy.

What was said in the beginning of the video, that the 'ordered' systems (dice or spheres) have more entropy than the disordered ones is not correct (if we look at the isolated entropy of the packing of dices and spheres). You might consider correcting this.
These systems do not reach a state of maximum entropy, but the minimum of an energy potential (like the Gibbs potential in thermodynamics). For the dices and the spheres this potential contains a gravitational energy term, which is the +m*g*h, where m is the total mass of the dices or spheres, g the gravitational constant and h the height of the center of mass of all the objects in question. The second term is an entropic one -c*S (c is some constant depending on the thermal energy or the shaking intensity in this case). The system now tends to adopt a configuration of minimum m*g*h-c*S. The close packing reduces h and this term dominates and therefore the dices or spheres adopt a packing where h is smallest possible even if S is not at its maximum. Here minimal h and maximum S can not be reached simultaneously.
To understand this consider there is no gravity (i.e. g=0) then only the entropic term -c*S is left in the potential and the system will adopt the state of maximum entropy (i.e. all dices and sphere floating randomly in the cylinder) at the mildest shaking (i.e. c is not zero). The second case is strong continued shaking. In this case c will be very large and m*g*h will become negligible (basically g can be assumed to be 0). Then again the dices and spheres will ‘float’ randomly in the cylinder due to the shaking.

1:30 most people dont know what entropy is at all though

Nice video, but Entropy in the original statistical mechanics sense of S=log(Omega) is good assumption ONLY in an energy conserving equilibrium system, what is generally called a microcanonical condition. In the case of macroscopic spheres (or dice) you have a dissipative system in which a lot of energy is dissipated into heat during collision and this is why you have to provide energy by vibration. This is a steady state and not an equilibrium one and entropy technically is not defined. Clearly you can use the dice example for pedagogical reason, but with a bit of care. You said: "any system wants to maximize entropy" this is not true. Let me give an exanple. If you wold have a mixture of two macroscopic spheres in a shaker they will have a strong tendency to demix with the big spheres going on the top (brazilian nuts effect). In a equilibrium system this will be nuch more unlikely (especially if rhe sizs ratio of the two spheres is not too large) because mixing increase the number of condigurations and consequently entropy.

*The 3 levels of entropy from less correct to more correct*
1: A system moving in the direction of a more disorderly state
2: A system moving towards a state of equilibrium
3: Energy and matter displaying the most statistically likely configurations
*Creating the arrow of time by moving towards that given configuration that can be more or less statistically likely but the ones which are the most likely are considered entropy

I watch tour channel mainly for how you make science topics fun and engaging with clever and novel experiments, but then every so often you deliver powerful insights expressed really intuitively and clearly. Thank you. Excellent work.

Every time I'm pretty sure I have a solid understanding of entropy, something comes along to prove me wrong! Nicely done.

"When enough chaotic and random events happens. Eventually, it leads to very predictable events."
Thats quite philosophical. So after enough observations, everything will be understood.

Now I don't understand entropy.

I'm joining team "I don't agree".
Because the dice in the ordered state have fewer opportunities to change position. If you keep doing that start stop they no longer move. Where in the disordered state they do move. Meaning the disordered state has more opportunities for the dice to move and therefor a higher level of entropy.

Hey! I like your video, but I have to ask for clarity. You treated the bowl of dice as a closed system while exerting outside forces. I believe you when you say the total entropy of the final system (inside the bowl only) increased, and the entropy of the drill also increased. Why was the outside force ignored? In another system where outside forces are ignored you may have decreases in entropy. But missing the outside force leaves the question open, does the entropy decrease in the bowl balanced by the entropy increase in the drill? Of course you explained that when looking at possible states it is favorable to pack. Further, thanks for the video, we fail to remember that "ordered" is a human imposed concept, if we define it as the low entropy states, then the bowl of none packed dice is more ordered than the packed one. But our brains like to call the packed state as more ordered.

This is not entirely correct and in fact could be incorrect. It’s not black and white. We have to keep this simple and not try to manipulate individual concepts but instead focus on the combined perspective.
Configurational entropy and positional entropy both need to be considered and calculated. If the extent of free volume significantly affects the number of Microstates that are accessible, then it’s possible the organized dice may have more entropy due to positional freedom. If the volume is more constrained, randomly orientated dice will have more entropy. We can not make the claim that one has more than the other without proper measurement.

One way to clarify what he's talking about is if you understand entropy as hidden information rather than disorder (the latter of which I despise as an explanation of entropy). In this sense, free space has no information content, amd thus no hidden information. By lowering the average free space in the local vicinity of the dice, we are hiding more information, because now any given die could have any 6 other die (or 5, if it's against a wall) directly pressing up against it. This is the massive increase in translational entropy that he's referring to.

My understanding is that the jar with the dice packs in an ordered way because that decreases the total gravitational potential energy of the dice, which makes that state more likely. If jar were in a state of weightlessness, the disorganised state would be more likely.

Great topic! I always learn something, realize how little I know about something and not understand something altogether in every episode, it’s awesome. Keep up the great work!

Which scientific articles or books were used in the video?

Ehy, I haven't checked the entropy calculations for the dice problem, but I have the feeling that the problem can be formalized in a way to define a free energy (akin to Gibbs free energy for chemical systems at conatan p and Helmoltz free energy at constant V) for the system as a combination of entropic effects and energetic effects. The energy in this case is given by the gravitational field and the constraints of the jar. If you had the same jar (with a lid, to make things simpler) in space, the average equilibrium state would be the one with the disordered dice scattered all over the place. I think that the only reason why you reach the ordered configuration with your shaking process is because that configuration corresponds to the local minimum of free energy for the system in the gravitational field. The shaking is just a way to go from local minimum to local minimum until you have reached the global minimum.
The fact that the equilibrium of systems subject to forces is not the maximum of entropy is a well known fact in chemical thermodynamics. In fact, almost always, maximizing the entropy doesn't give you the chemical equilibrium of a system. Otherwise you could not explain things like the formation fo crystals or even molecules at all.
The second principle of TD tells you that entropy is a thermodynamic potential only strictly for isolated systems: for all other systems, you need to find a suitable TD potential to minimize or maximize given the constraints of the system. The only thing that TD (specifically, non equilibrium TD) tells you about entropy is that any irreversible process comes with a positive entropy PRODUCTION (not entropy): but for any non-isolated system, you can always let entropy in and out of the system by suitable fluxes of heat or mass.
Finally, I am sure you are familiar with the fact that since Boltzmann's pioneering work on the statistical interpretation of entropy, there have been several different definitions of "entropy" related to microstates of the system, more or less coherent with each other and the classic definition of entropy proposed by Clausius. Even without entering the rat's nest of which statistical definition of entropy you are referring to, I would honestly be surprised if you cannot find a coherent formalism in terms of free energy to describe the entropy of the dice so that it indeed decreases as it approaches final metastable configuration, thus attributing the driving force to an energetic factor.

Free volume is not created. The many random small amounts of volume have been combined into one larger volume but no extra has been added.

if only science class was this interesting

Greetings from Slovakia

1:10 gravity, the pieces want to be at the lowest point possible so they pack together to make them as low as possible

The second law of thermodynamics applies to closed systems, not all systems in the universe, nor all theoretically possible universes... But an interesting video that will be fun to think about.

Your videos make every hard concept seem so fun and easy

I prefer to think of entropy as pointing in the direction of the arrow of time - jiggling and jostling over time will tend to produce the most common configurations. This only holds if all configurations are equally available and aren't sticky. Natural filters in life put a non-random bias against this jostling, from your example here to the gravity wells of stars and the motion of beaches, or Life's Ratchet in the cellular machinery. If once a random state occurs that locks in a position (like your orderly dice that can no longer move) then they will tend to order up even if order up states are less common, because they stick. No matter how slow the decay is or how uncommon the state of a random decay is, Schrodinger's cat will die when it happens and will stay dead (cat will randomly die but not randomly resurrect), so over long time you are much more likely to find a dead cat than a live one. Entropy was meant to describe states that are fully free to interact in the system, not natural filters. It doesn't break physics, it just doesn't fit that model.
If you think of entropy not as of particle concentration or arrangement, but as the most likely outcomes over long times scale including non-random natural filters, then a compact star or beautifully orderly beach sand are actually low entropy as the dead end of the jostling options. This kind of one-way-ness also applies in other realms like gambling - where no matter how much you win you still can still risk all and lose all, but once you are broke you cannot un-lose. The house always wins even if you have slightly favorable odds, because even a less common disaster cannot be recovered while all cumulative success is just one bad roll from being wiped away.

Entropy? :D
This is more about a constant field of gravity acting on the contents locking them in place, and the constant work input by agitation that allows each die/bead to move out of its current local minima and fall into its new place. Once slotted into positions, gravity and force from their neighbors restrict them from moving out of place. This effectively locks them in place. It just so happens that the most 'restrictive' spaces are also the most space-efficient structures (highest packing efficiency), and crystalline structures are quite space-efficient.
Hence spheres forming a face-centered cubic instead of body-centered cubic or other patterns.
Given the magnitude of forces at play, they drown out any entropy changes you see in the system.
Try doing this test without agitation and gravity messing with the system. Try suspending them in solution of similar density. If you let the solution evaporate or drain slowly, it might shed a decent light on crystal formation too. (drain too fast and they will look more disordered, and 'crumbly' too) :D

really cool video, and love how you just casually throw in chat GPT in like "if I ask it the answer WILL be wrong", 10/10 chefs kiss

1:45 Well Said Remember Folks, AI will give you the Popular Answer, not Necessarily the Correct Answer.
[Usually Popular = Correct AND you also want to Double Check some other way]

Good Morning!😃

Well, this was absolutely fascinating.

(0:02) Let me guess... You bought a cheap bag of D6 dice that needed to have their dots filled in with a marker. 😉

I always understood entropy as the drive towards a stable state where no work is done, e.g. when all heat is evenly distributed in the universe, there is no transfer of energy (because heat doesn't pass from cooler to hotter (thank-you to Flanders and Swan for their song about the laws of thermodynamics) and everything is equally hot. The dice stop moving once they are aligned because the are then at their most stable configuration. In an earthquake, things fall down because being on the floor is their most stable state.

Which simulation software at around 4:00?

Just for this... I subscribe. Didn't expect to learn anything new... but this gives me a new understanding on how to perceive the world. No one ever explained me entropy in class, and I guess I missed out a little in my understanding of this concept.

Since when does ChatGPT "represent most people"? STEM bros really crumble at the thought of social research, huh? You could've easily made a poll of your audience or cited popular definitions of entropy in recognized dictionaries but you chose the laziest way possible, somehow equating an LLM with "most people" as if it's a fact.

This really changed my understand of entropy and appreciate the perspective that life is an emergent property of a system that has evolved to increase entropy while efficiently dissipating energy. The variety of life on Earth shows that a relatively small number of different chemical elements can assume quite a variety of arrangements. Carbon is entropy's strongest proponent in that realm.

4:07 you say there's no forces acting on the particles making them coil together but actually in the simulator you used the electromagnetic force is simulated, which is what's pulling them together

Finally! Entropy explained in such an eloquent and simple way! Thank you for clearing up this seemingly arcane concept!

Once the universe reaches full entropy, if ever, that will be perfect order. Or as close as you can get to it. How people come to the conclusion that entropy is chaos is beyond me

I saw it differently. The random dice in the glass has a higher potential energy state than the organized stacked state hence the jiggling tends to organize the dice.

2:09 you lost me

This is of the most interesting take on Entropy I have ever seen. Very nice explanation!

I think the way that communicates best how I understood entropy is "The inverse deviation from an object's state at the end of time," meaning, the more entropy increases, the more closely an object will reflect the state it would be in as time approaches infinity, and that entropy is used as a way to gauge how far away an object is in an initial state from the state it will reach at the end of time

Nice video! Did you ever consider making the background static when showing equations (4:48) ?

I've quite recently finished writing my PhD thesis on entropic phase transitions in some specific systems. I have a whole section of a chapter devoted to "trading" one type of entropy for another type for a net entropic gain. I find this phenomenon very fascinating and almost each one of my scientific papers has a short, "intuitive" discussion how it is applied to the case on hand.

While the entropic force is a major factor in a rubber band's retraction, it's not the sole force at play. There are also:
Enthalpic Forces: These arise from changes in the internal energy of the rubber band when stretched. Stretching stores energy in the polymer bonds, and releasing the band allows this energy to dissipate.
Cross-linking: The polymer chains in rubber are often cross-linked, creating a network that resists deformation. This contributes to the overall restoring force.
The Dominant Force:
In most everyday situations, the entropic force is the dominant factor in a rubber band's behavior. This is why heating a rubber band (increasing entropy) causes it to contract, and cooling it (decreasing entropy) makes it stretchier.
Important Note: The balance between entropic and enthalpic forces can change under extreme conditions (e.g., very high or low temperatures) or with different types of rubber.
In summary: The entropic force is a significant factor in a rubber band's tendency to return to its relaxed state, but it's not the only force involved. Enthalpic forces and cross-linking also play a role, although their contribution is usually smaller in typical scenarios.

Your vids and explanations have really improved lately! Keep goin good sir

I finally get the description of Entropy in a clear short way. Thank you 👍🏻

You are the first person to actually explain entropy simply.

I’m pretty sure the example of the rubber band stops being only entropic force the moment the band has to be stretched rather than just loosely in a line.

I came out of this video feeling like I have a better understanding of entropy than ever before. Well done!

This is why science is so great. Its about studying whats actually going on regardless of preconceived ideas or beliefs. Properties of the Universe can get confusing (especially when there are multiple things going on and many variables). Science is studying each one, recording data, repeating, recording, etc.
Humans love to see one event and assume they know everything from it...we know thats not the best way yet here we are in 2024 with 10s of millions who would rather believe what they want to more than what is real.

This video gives me a new view of force, force is a difference of possibility, interesting

I recall reading that this is why cables in a box tend to get tangled with each other (or headphones in your pocket).

I love how your simple questions and demonstrations arouse the curiosity of so many. I never considered the entropy of a cup of dice before, for example.

There are a couple things that don't make sense to me about this. And these aren't rhetorical questions, I absolutely believe your account of how it works since you know much more about it than I do. These are points of genuine and self-acknowledged confusion.
1) If entropy depends on number of possible configurations, shouldn't the dice still have higher entropy when more disordered? You say they have higher entropy when tightly packed because there's more free volume above them, but it seems to me the number of possible configurations of the dice is higher the more volume the dice _do_ occupy, not the more volume they _don't_ occupy. I realize the dice are actually separate objects, but if we think of the volume they occupy as this connected, amorphous cloud, then shouldn't there be more possible places we could find any given die in the larger _that cloud_ is, _not_ the larger the _air above it_ is? I guess what I'm getting at is, if we consider only the configurations where the dice are tightly packed, it seems to me the probability of finding any dice in the unoccupied volume above the dice, that volume you described as "free," is by definition _zero._
2) Also, generally, how valid is it, really, to discuss entropy as a number of _possible_ configurations of a system which has a _known fixed_ configuration if closely observed? If die A _is_ at position P, and die B _is_ at position Q, then the probability of finding die A at position Q or die B at position P is zero. I know I just got through saying we can think of the occupied volume of the dice as this connected, amorphous cloud, but can we really? Isn't that occupied volume actually a precise crystal structure in the exact shape of a whole bunch of cubes, with pockets between them excluded from the manifold? By that logic, it seems to me that _everything_ has zero entropy at all times. I realize this notion of exact knowability doesn't hold at a quantum scale, where the uncertainty principles take effect, but we aren't _at_ that scale.

You're forgetting the most important part of the equation, you. Conscious intervention. You interfered. You added order to a disordered system. You put it back together. You pulled the rubber band. If you haven't looked into Emergence Theory, you should.

I'm not an expert on entropy, but the easier explanation in my mind is that the aligned dice simply have more possible states available. Consider 100 dice stacked in the bottom of the container - each cube can be swapped for any other so you have a total of 100! possible states. Now imagine that 20 of them are sitting on the edge - each of the cubes lying flat can be swapped with each other flat cube (80! possible states), and each on-edge cube can be swapped with each other on-edge cube (20! possible states). So the mixed orientation configuration has 80! x 20! possible states which is SIGNIFICANTLY fewer states and therefore lower entropy. Adding additional orientations here lowers the entropy. (Yes, this is a simplification of the situation)
I'm not yet totally convinced that the "free volume" concept is very helpful in understanding the increase in entropy with the dice here even though the difference in volume will certainly play a role in the number of states.
Although it's pretty surprising, I wouldn't say there is anything "mysterious" about this "force". Where there are MANY more possible ways for a system to do something, the system will tend to eventually do that thing. At least, that's how I like to think about it.

Mario, you misunderstood entrophy

When you jostle the dice, their gravitational potential energy is being dissipated as sound and heat, so they tend towards a "ground state" where their potential energy is minimized (by being packed as low as possible). The entropy of the dice does indeed decrease because there is only one "ground state" (up to rotation of each layer). It's possible for the dice's entropy to decrease because they are not a closed system - you are not counting the microscopic degrees of freedom where the sound and heat end up as part of the system, and if you did, total entropy would increase.
Another way of looking at it is if there were no energy dissipation into those microscopic degrees of freedom, then the dice collisions would be perfectly elastic and they would keep bouncing around instead of settling.

Cool video! I have seen many confusing explanations of entropy, but on of the better ones is "Entropy states 'that which is most probable will probably happen.'" In a random system, the probabilities reflect that in disorder. If the rules of the system are ordered, the result will generally be ordered. In application it's a little more complicated than that, but in general essence it seems to be right. So I guess the entropic force is the tendency of the system to align to its underlying probabilities.

In thermodynamics, we were taught that entropy is the amount of energy that is not available to do useful work. As such then, something that is not available cannot create a force. External work was done on the dice and nails to get them into the ordered pattern. They did not get that way by themselves.

Finally someone who gets it and can actually explain it in a good way.. Damn, not even my university profs got the concept of entropy! The whole "you can't unmix the marbles!" and other demonstrations of randomness to explain entropy completely ruined the idea in the public mind. We need more of these videos!

I love this video you explained so much
The ideas of self organizing systems and entropy seem totally at odds until you bring up these cool examples

Interesting fact is that with the most symmetric geometrical shape, the sphere, you cannot get entropy by shaking. This is because there are two ways of 'closest sphere packing' (cubic and hexagonal). Both packing structures will occur when you pile up balls/spheres and shake them. They will form random groups within the pile of spheres, and the bounderies between those groups will only get more defined the more you shake.

"Go clean your room"
Me preparing my CaseOh clone to make an earthquake:

The best explanation of entropy on the internet

Fun fact, entropy is why loose wires/strings get tangled all the time. One thing always helps: connect one end to the other, this restricts the number of variations in knots it can have (to 0).

This video reminds me of my younger days back in the 90s. I used to prepare for raves by visiting a stimulating trader I knew.
I was still young and naive and didn't understand why this friend would always take out a large bowl filled with dice and marbles. He explained that sometimes its not enough to hide the screwdriver.
As my experience grew and I met different people I understood, Dude was just protecting his electronics with that bowl.

This was very informative, thanks for the video. It would be really cool to see more everyday examples of entropic forces

This is why I love Thermodynamics. This is not only about "X" particles or things moving and doing things, it's something more fundamental.

Marvellous! Best explanation I have ever seen. I almost get it now.

I always looked at entropy as the ending of something or decay but there's more to it. The heat death of the universe was the main example of entropy i had used to try to figure out what entropy is/does. Even in this video towards the beginning it seemed to me more like the tendency to even out, before you explained it more.
So what I get from this is entropy is the tendency to or force of changing to a state of more potential from a state with less potential.

If the organised dice are basically identical it doesn't matter which position they take, it's essentially the same state, so low entropy.
If they are disorganised it does matter which position they occupy resulting in more states = more entropy.
It shows because you needed to put in energy by shaking/twisting to organise them.

When you heat a steel spring, its spring force decreases as the steel gets softer.
When you heat a rubber band, its spring force increases, because the molecular chains wiggle faster.

It still seems weird to call it a "force", but that's a great explanation of the increased entropy of "free space".

I took physics at McGill university with Adv Stat Mech I and II and never heard of a better explanation. Another amazing video!

That "ow" was expected but it still threw me off guard

I'm skeptical that this video is correct. At 2:39, the amount of free volume per die has not changed at all; it is simply a different arrangement. There are, in fact, fewer possible states with the dice packed orderly than randomly. The dice stacked like that is the same as all of the air in a room being in just one half of it: it wouldn't be a stable state if there wasn't something else going on. What you have accomplished is more equivalent to a phase change, from an amorphous solid to a crystalline solid. The phase change is brought about by the loss of gravitational potential energy (as sound and heat) as the dice settle into lower positions. Yes, entropy of the system has increased, but no, entropy of the stacked dice themselves is not greater.
This should be testable by performing the same experiment in a zero-g environment. I, unfortunately, lack the resources to go to space to perform the test. Any ISS astronauts here who want to play with dice?