Entropic gravity is a compelling framework. I think that most Physicists admit that it would be nice to believe that the yet unknown theory of everything is microscopic and quantum mechanical, and that the global and exquisitly weak force of gravity emerges from that theory as a sort of accounting error.
But there are so many potential assumptions baked into these theories that it's hard to believe when they claim, "look, Einstein's field equations."
mr_mitm 4 hours ago [-]
What are some of the most problematic assumptions in your opinion?
nathan_compton 5 minutes ago [-]
I'm not an expert in this field but I think reproducing realistic gravitational interactions seems to require a lot of fiddly set up with heat baths etc.
gus_massa 1 hours ago [-]
> I think that most Physicists admit that it would be nice to believe that the yet unknown theory of everything is microscopic and quantum mechanical,
I agree.
> and that the global and exquisitly weak force of gravity emerges from that theory as a sort of accounting error.
Nah, it's probably just another weird family of bosons, just like the other forces.
From the article:
> Entropic gravity is very much a minority view. But it’s one that won’t die, and even detractors are loath to dismiss it altogether.
pif 5 hours ago [-]
As an experimental physicist, I refuse to get excited about a new theory until the proponent gets to an observable phenomenon that can fix the question.
lewdwig 5 hours ago [-]
The problem with emergent theories like this is that they _derive_ Newtonian gravity and General Relativity so it’s not clear there’s anything to test. If they are able to predict MOND without the need for an additional MOND field then they become falsifiable only insofar as MOND is.
dawnofdusk 8 minutes ago [-]
Deriving existing theories of gravity is an important test of the theory, it's not a problem at all. It's only a problem if you can only do this with more free parameters than the existing theory and/or the generalized theory doesn't make any independent predictions. Seems like in the article the former may be true but not the latter.
JPLeRouzic 4 hours ago [-]
Please, how is the article related to MOND's theories?
lewdwig 3 hours ago [-]
In general, they’re not. But if the only thing emergent theories predict is Newtonian dynamics and General Relativity then that’s a big problem for falsifiability. But if they modify Newtonian dynamics in some way, then do we have something to test.
> FWIU this Superfluid Quantum Gravity [SQG, or SQR Superfluid Quantum Relativity] rejects dark matter and/or negative mass in favor of supervaucuous supervacuum, but I don't think it attempts to predict other phases and interactions like Dark fluid theory?
> A unified model must: differ from classical mechanics where observational results don't match classical predictions, describe superfluid 3Helium in a beaker, describe gravity in Bose-Einstein condensate superfluids , describe conductivity in superconductors and dielectrics, not introduce unoobserved "annihilation", explain how helicopters have lift, describe quantum locking, describe paths through fluids and gravity, predict n-body gravity experiments on earth in fluids with Bernoulli's and in space, [...]
> What else must a unified model of gravity and other forces predict with low error?
neuroelectron 38 minutes ago [-]
The speed of light is C, a constant. Mass is composed of these particles that are bound by C. Because they are vibrating, a lot of that speed is being wasted in brownian motion. So the denser it is, the more your average vector is going to be toward more dense brownian motion as the particles interact and induce more brownian motion. The gradient has a natural sorting effect.
Seems pretty intuitive to me. The question remains though, what is this density made of since gravity exists in a vacuum? Quantum fluctuations popping in and out of reality? Does this infer that quantum fluctuations are affected by mass as well? It would seem so since in Bose Einstein Condensate, what is "communicating" the state across the BEC if the particles are no longer interacting?
danparsonson 28 minutes ago [-]
> Seems pretty intuitive to me
OK, but it's nonsense. Apart from whatever-you're-talking-about-with-C, quantum fluctuations are not Brownian motion; Brownian motion is the visible effect of a lot of invisible particles interacting kinetically with macroscopic particles like dust, making those macroscopic particles appear to vibrate of their own accord. Atoms that cannot be seen in a microscope flying around in straight lines and randomly bumping into dust particles that can be seen.
You can see it in action with a simple random walk program. Allow the steps to decrease in size toward one side of the screen and they will statistically be sorted toward the shorter steps.
steamrolled 31 minutes ago [-]
> Because they are vibrating, a lot of that energy is being wasted in brownian motion. So the denser it is, the more your average vector is going to be toward more dense brownian motion as the particles interact and induce more brownian motion ... Seems pretty intuitive to me.
So this is why warm objects weigh more?
Xcelerate 15 minutes ago [-]
Warm objects actually do weigh more than their counterfactual cold versions haha. The stress energy tensor is the quantity to look at here.
This reads like a sarcastic quip so, sorry if it wasn't but, they do. Solve for m in E=mc^2 and see what happens when objects have more energy.
neuroelectron 15 minutes ago [-]
Yes, hotter things generally become less dense and weigh less but the number of particles stays the same and the mass stays the same...
And gravity exists in a vacuum...
So I'm not talking strictly about particle interactions, that! Why I addressed this.
The key is C, constant speed and the random motion becoming more dense. The motion not the particles.
hoseja 6 hours ago [-]
Like some sort of buoyancy?
dist-epoch 7 hours ago [-]
We all know that life on Earth gets it's energy from the Sun.
But we also know that's an approximation we tell kids, really life gets low entropy photons from the Sun, does it's thing, and then emits high entropy infrared waste heat. Energy is conserved, while entropy increases.
But where did the Sun got it's low entropy photons to start with? From gravity, empty uniform space has low entropy, which got "scooped up" as the Sun formed.
This is just a question about the origins of inhomogeneity in the universe. The prevailing theory is cosmic inflation, I believe: in the early universe a quantum field existed in a high entropy state and then the rapid expansion of space magnified small spatial inhomogeneities in the field into large-scale structures. What we see as "low entropy" structures like stars are actually just high entropy, uniform structures at a higher scale but viewed from up close so that we can see finer-scale structure.
uncircle 7 hours ago [-]
Your question fascinated me. Googling "where did the Sun got its low entropy" I also came across these explanations:
"Solar energy at Earth is low-entropy because all of it comes from a region of the sky with a diameter of half a degree of arc."
also, from another reply:
"Sunlight is low entropy because the sun is very hot. Entropy is essentially a measure of how spread out energy is. If you consider two systems with the same amount of thermal energy, then the one where that energy is more concentrated (low entropy) will be hotter."
Probably it's a bit of both. I'm not sure I understand your hypothesis about the Sun scooping up empty, low-entropy space. Wasn't it formed from dusts and gases created by previous stellar explosions, i.e. the polar opposite of low entropy?
im3w1l 4 hours ago [-]
The universe was low entropy at the time of the big bang, and even though entropy is steadily rising, the universe is still pretty low entropy.
dist-epoch 7 hours ago [-]
I read the gravity explanation for the sun low entropy in the "Road to Reality" book from Roger Penrose. Asked Gemini to summarize the argument (scroll to end)
It's also in his previous book "The Emperor's New Mind: Concerning Computers, Minds and The Laws of Physics", along with a lot more. Strongly recommended (even though after reading a lot of Greg Egan, my views on consciousness somewhat shifted towards "classical computation can do it, too".)
aurareturn 4 hours ago [-]
But where did the Sun got it's low entropy photons to start with? From gravity, empty uniform space has low entropy, which got "scooped up" as the Sun formed.
From the Big Bang originally. We don’t know what caused the Big Bang.
gavinray 2 hours ago [-]
The end of the previous Big Bang, a-la Big Bounce ;^)
"It's turtles all the way down."
mjanx123 4 hours ago [-]
The photons do not have entropy.
The photons from Sun are hot, the space around Sun is cold, the system has a low entropy.
If the space around Sun was as hot as the photons, the entropy would be high.
omeysalvi 7 hours ago [-]
"There’s some kind of gas or some thermal system out there that we can’t see directly" - The Ether is back on the menu boys
grumbelbart2 4 hours ago [-]
It has been back for a while in the form of quantum fields.
whycome 7 hours ago [-]
Caloric. Dark matter. Cosmological constant.
We like placeholders for the unknown.
killerstorm 5 hours ago [-]
Isn't that how equations get solved?
Pretty much anything known entered through such placeholder, it's just that equations could be connected more easily.
It's not like Higgs field is something you can directly observe
Keyframe 4 hours ago [-]
Right, but you can push unknowns into tmp vars only so much before you have to introduce constraints, otherwise it's all downright undetermined. You have to inject a structure into the placeholder soup or you're just pushing ambiguity around with no real net gain.. which is also fun to play around, question is will you get a paper out of it or even paid if you play like that to no end.
jstanley 5 hours ago [-]
Maybe, (I don't know), but it's easy to accidentally come up with a theory of "mysterious stuff" that appears to explain something, but neither constrains your expectation nor provides predictions.
The Phlogiston theory made one crucial prediction - that the speed of light would vary depending on the observer’s movement through the ether. That prediction turned out to be famously wrong.
FrustratedMonky 2 hours ago [-]
Its a process.
You find some un-identified variables.
Form some hypothesis, try to narrow it down.
Sometimes it is a discovery, new particle, and sometimes it is nothing.
But that is how science works.
At some point in time, everything was an unknown, and people had to work with unknowns.
This whole movement from the 'right' that all science has to know the answers ahead of time in order to justify spending money, is hindering progress. How can you know the results are worthwhile, in order to justify funding, before doing the research to know the results?
RGamma 2 hours ago [-]
Primordial black holes.
jstanley 6 hours ago [-]
Don't forget phlogiston.
holowoodman 6 hours ago [-]
Virtual Particles!
bandrami 6 hours ago [-]
Was that de Broglie's thing? I always thought it didn't get a fair shake
holowoodman 6 hours ago [-]
Virtual particles and related effects are actually widely accepted and experimentally proven (at least partially). Current physics wouldn't really work without them, or at least something that looks the same.
The gist of it is, that quantum mechanics prevents vacuum from really being empty. Any finite-size system or any system with some kind of influence/force/anything will have a lowest energy state that is not actually zero energy but slightly above. Which means that this non-zero can fluctuate and on occasion pair-produce and pair-annihilate particles (probability inversely depending on pair energy).
And yes, this sounds like some kind of ether...
tsimionescu 4 hours ago [-]
The Wikipedia article that you quote is quite explicit that, while virtual particles are a widely accepted mathematical tool, they're actual existence of elements of reality is very much not widely accepted, and definitely nowhere close to "experimentally verified". It's in fact considered impossible to verify experimentally, even in principle.
Note that there are many very widely used physical theories that include mathematical elements that are not necessarily assigned any physical meaning. The Poynting vector in classical electrodynamics, for example, carries no widely accepted physical meaning, even though it appears in many well verified and used calculations. This doesn't make the theory suspect or anything, I'm not trying to imply that - simply that virtual particles being "real" or not is a mostly philosophical question that has no widely accepted consensus.
holowoodman 3 hours ago [-]
Those particles are virtual in that they don't really exist, so you are right that proving them isn't actually possible, because they are simply not there, just virtually, in our mathematical imagination. In quantum mechanics[1], this isn't really a "doesn't exist" kind of thing, rather it means that the wave function is there, leading to the (slim) possibility of existence through some kind of wave function collapse.
What is proven is that e.g. vacuum energy / zero point energy exists (not actually in the StarGate sense of extractable energy, just that the lowest energy state of any physical system isn't zero), and that the Casimir effect exists. Vacuum energy directly leads to virtual particles through pair production (which is a proven mechanism, at high energies, for low energies we do suspect that there isn't a cutoff there), and also influences e.g. high-energy cosmic rays leading to an observed high-energy cutoff (although there are other possible explanations for that cutoff and lack of very-high-energy cosmic rays). The Casimir effect is most easily explained by virtual particles and vaccum energy.
In Hawking radiation, the idea is actually that virtual particles through interaction with the gravity of the black hole become real particles. The event horizon actually makes those wave functions collapse such that real particles start to exist. Hawking radiation hasn't been observed yet, however.
[1] non-Kopenhagen QM has the same consequences, it's just even harder to explain actually.
griffzhowl 4 hours ago [-]
You're probably thinking of the de Broglie-Bohm pilot wave theory, where there are actual particles with determinate trajectories at all times, which are probabilistically guided by a wave. I think they main problem with this idea is that it can't be made relativistically invariant, and so it can only be used for systems with low realtive velocities of its components.
OTOH de Broglie for one of the central ideas in the development of quantum mechanics: he inverted Einstein's idea about photons, which were previously thought to be waves but Einstein showed how they came in particle-like quanta. de Broglie realised you could apply the same thinking to matter, which had previously been thought of as particles, and describe them using waves. Subsequent observation of wavelike dynamics (diffraction) of electrons in the Davisson-Germer experiment got de Broglie the Nobel prize.
2 hours ago [-]
metalman 6 hours ago [-]
gravity=time
brador 5 hours ago [-]
Anti matter is created and repulsed and expelled, leaving a vacuum, things get sucked into that vacuum, creating the illusion of gravity, that’s my novel theory.
IAmBroom 2 hours ago [-]
Vacuums don't suck; high pressure repels.
Similarly, umbrellas aren't places to stand under when it's not raining.
john_moscow 8 hours ago [-]
Space exists around things with mass. Also, above-absolute-zero temperatures cause particles to jump around randomly.
Now if there is "more space" around particle A, particle B will have a slightly higher statistical chance of randomly jumping closer to it, than farther.
Rinse-repeat. Gravity as we know it.
meindnoch 6 hours ago [-]
>Also, above-absolute-zero temperatures cause particles to jump around randomly.
Does it? A single free particle won't "jump around randomly". Thermal motion is plain Newtonian motion with an extremely high rate of collisions. There's nothing random about it (let's put quantum things aside for now).
If space existed around things with mass, then what would you call the emptiness that replaces space the further you go away from things with mass?
bravesoul2 7 hours ago [-]
> particle B will have a slightly higher statistical chance of randomly jumping closer to it,
Why?
Also how do you explain acceleration due to gravity with that model. How do you explain solid objects?
MaxikCZ 6 hours ago [-]
My guess would be the answer is right in the part before you quote? If theres more "space" (imagining more space coordinates possible) for me on the left than on the right, me jumping to a random location would statistically move me left.
Repeating results in movement, getting closer to the object intensifies this effect, results in acceleration.
Solid objects are products of electric charge preventing atoms/particles from hitting each other, I dont think that has to have to do anything with gravity in this example?
bravesoul2 2 hours ago [-]
I don't understand the more space thing then. Is this more space due to spacetime curvature or something else.
E.g. if we have earth and moon:
O o
Why is there more space from the moon towards earth than away?
jblezo 14 minutes ago [-]
Spacetime curvature.
Like if you dropped the earth on a giant sheet, it would stretch the sheet more than what the moon would have.
enriquto 7 hours ago [-]
Sounds fun!
Would this imply that cold objects have weaker gravity?
psittacus 7 hours ago [-]
Isn't this something we already know from the mass–energy equivalence? In the same way that a nuclear reaction that produces heat must cost the object mass (and therefore gravitational pull)
Quarrel 6 hours ago [-]
It does, but because you have to divide the energy change by c^2, it is really really hard to detect it, and mostly overwhelmed by other effects of the heating/cooling.
enriquto 5 hours ago [-]
why do the units matter here? Under this theory, will a body at absolute zero have no observable mass? No attractive field around it, no inertia if you try to move it.
Woansdei 7 hours ago [-]
sounds more like the reverse to me, movement away from denser areas (less space), so like water leaking out of a container.
meindnoch 6 hours ago [-]
I don't get it.
To me, entropy is not a physical thing, but a measure of our imperfect knowledge about a system. We can only measure the bulk properties of matter, so we've made up a number to quantify how imperfect the bulk properties describe the true microscopic state of the system. But if we had the ability to zoom into the microscopic level, entropy would make no sense.
So I don't see how gravity or any other fundamental physical interaction could follow from entropy. It's a made-up thing by humans.
antonvs 6 hours ago [-]
Your perspective is incorrect.
Physical entropy governs real physical processes. Simple example: why ice melts in a warm room. More subtle example: why cords get tangled up over time.
Our measures of entropy can be seen as a way of summarizing, at a macro level, the state of a system such as that warm room containing ice, or a tangle of cables, but the measure is not the same thing as the phenomenon it describes.
Boltzmann's approach to entropy makes the second law pretty intuitive: there are far more ways for a system to be disordered than ordered, so over time it tends towards higher entropy. That’s why ice melts in a warm room.
aeonik 4 hours ago [-]
My take, for what it's worth,
Entropy isn’t always the driver of physical change, sometimes it’s just a map.
Sometimes that map is highly isomorphic to the physical process, like in gas diffusion or smoke dispersion. In those cases, entropy doesn't just describe what happened, it predicts it. The microstates and the probabilities align tightly with what’s physically unfolding. Entropy is the engine.
But other times, like when ice melts, entropy is a summary, not a cause. The real drivers are bond energies and phase thresholds. Entropy increases, yes, but only because the system overcame physical constraints that entropy alone can’t explain. In this case, entropy is the receipt, not the mechanism.
So the key idea is this: entropy’s usefulness depends on how well it “sees” the real degrees of freedom that matter. When it aligns closely with the substrate, it feels like a law. When it doesn't, it’s more like coarse bookkeeping after the fact.
The second law of thermodynamics is most “real” when entropy is the process. Otherwise, it’s a statistical summary of deeper physical causes.
lumost 59 minutes ago [-]
What makes entropy interesting is that you can describe many physical processes through analysis of the systems degrees of freedom. This pattern repeats regularly despite the systems being radically different.
So you can interpret entropy as being about as real as potential energy or newtons laws. Very useful for calculation, subject to evolution laws which are common across all systems - but potentially gives way as an approximation under a finer grained view (although the finer grained view is also subject to the same rules)
ludwik 6 hours ago [-]
> there are far more ways for a system to be disordered than ordered
I'm a complete layman when it comes to physics, so forgive me if this is naive — but aren't "ordered" and "disordered" concepts tied to human perception or cognition? It always seemed to me that we call something "ordered" when we can find a pattern in it, and "disordered" when we can't. Different people or cultures might be able to recognize patterns in different states. So while I agree that "there are more ways for a system to be disordered than ordered," I would have thought that's a property of how humans perceive the world, not necessarily a fundamental truth about the universe
mr_mitm 4 hours ago [-]
You only hear these terms in layman explanations. Physics has precise definitions for these things. When we say "ordered", we mean that a particular macrostate has only few possible microstates.
Details can be found in any textbook on statistical mechanics.
Gravityloss 2 hours ago [-]
Exactly. The coin flipping example is a very nice way to put it. It works since the coins are interchangeable, you just count the number of heads or tails.
If the coins were of different color and you took that into account, then it wouldn't work.
It's not intuitive to me what gravity has to do with entropy though, as it's classically just a force and completely reversible (unlike entropy)? Ie if you saw a video of undisturbed objects only affected by gravity, you couldn't tell if the video was reversed.
hackinthebochs 5 hours ago [-]
Think minimum description length. Low entropy states require fewer terms to fully describe than high entropy states. This is an objective property of the system.
sat_solver 4 hours ago [-]
You're thinking of information entropy, which is not the same concept as entropy in physics. An ice cube in a warm room can be described using a minimum description length as "ice cube in a warm room" (or a crystal structure inside a fluid space), but if you wait until the heat death of the universe, you just have "a warm room" (a smooth fluid space), which will have an even shorter mdl. Von Neuman should never have repurposed the term entropy from physics. Entropy confuses a lot of people, including me.
hackinthebochs 2 hours ago [-]
Maxwell's demon thought experiment implies they are the same concept. Given a complete knowledge of every particle of gas you can in principle create unphysical low entropy distributions of the particles. This[1] goes into more detail.
And somewhat surprisingly the heat death of the universe is the maximal entropy state.
Because there are an infinite number of microstates (all the particles are interchangeable) that lead to the same macrostate: nothing happening for ever!
zmgsabst 3 hours ago [-]
“Number of terms” is a human language construct.
hackinthebochs 3 hours ago [-]
No, it's a representation construct, i.e. how to describe some system in a given basis. The basis can be mathematical. Fourier coefficients for example.
zmgsabst 1 hours ago [-]
Mathematics is a human language. It being a formal language doesn’t change that.
Further, it’s not objective: you’re choosing the basis which causes the complexity, but any particular structure can be made simple in some basis.
hackinthebochs 35 minutes ago [-]
Mathematical notation is a human invention, but the structure that mathematics describes is objective. The choice of basis changes the absolute number of terms, but the relative magnitude of terms for a more or less disordered state is generally fixed outside of degenerate cases.
amelius 5 hours ago [-]
In a deterministic system you can just use the time as a way to describe a state, if you started from a known state.
refactor_master 6 hours ago [-]
I think original post is confused exactly because of “tangled chords” analogies. Something being “messy” in our daily lives can be a bit subjective, so using the same analogies for natural forces may seem a tad counterintuitive actually.
Maybe it would be more fitting to say that it just so happens that our human definition of “messy” aligns with entropy, and not that someone decided what messy atoms look like.
I’d say a bucket of water is more neat than a bucket of ice, macroscopically.
geon 3 hours ago [-]
It has been suggested that time too is derived from entropy. At least the single-directionality of it. That’d make entropy one of the most real phenomena in physics.
meindnoch 5 hours ago [-]
>Simple example: why ice melts in a warm room.
Ice melting is simply the water molecules gaining enough kinetic energy (from collisions with the surrounding air molecules) that they break the bonds that held them in the ice crystal lattice. But at the microscopic level it's still just water molecules acting according to Newton's laws of motion (forgetting about quantum effects of course).
Now, back on the topic of the article: consider a system of 2 particles separated by some distance. Do they experience gravity? Of course they do. They start falling towards the midpoint between them. But where is entropy in this picture? How do you even define entropy for a system of 2 particles?
tsimionescu 4 hours ago [-]
> But where is entropy in this picture? How do you even define entropy for a system of 2 particles?
The answer is that this doesn't happen in a system with only 2 particles. The idea of gravity as an entropic phenomenon is that you introduce some other kind of particle that permeates spacetime, so there is no system that only contains 2 particles. You may use some idea like virtual particles from quantum field theory, or you may define "quanta of space time" as something that is not technically a particle but basically works like one in a handwavy sense.
But the basic point of these entropy based theories is to explain gravity, and typcilaly spacetime itself, as an emergent result of a collection of numerous objects of some kind. This necessarily means that they don't make sense if applied to idealized systems with very few objects - which is why they typically posit such isolated systems simply can't actually exist in reality.
ccozan 5 hours ago [-]
Let me try to answer. Let's say the particles are experiencing gravity as a natural entropy phenomena. They will attract until they become so close that they are now seen as a single particle. The new system has a lower entropy and a higher gravity than before.
Explanation seems very rudimentary but that is the gist of the theory.
From my point of view, I might add the layer of information density. Every quantum fluctuation is an event and the more particles the more information is produced in a defined space volume. But there is no theory of information that is linked to the physics so ...that let me leave as that :).
HelloNurse 6 hours ago [-]
But "disordered" and "ordered" states are just what we define them to be: for example, cords are "tangled" only because we would prefer arrangements of cords with less knots, and knots form because someone didn't handle the cords carefully.
Physical processes are "real", but entropy is a figment.
dekken_ 5 hours ago [-]
I believe you are correct.
Entropy is not a physical quantity, it is a measure of how far a system is from equilibrium.
Lots of people talk about order/disorder or macro and micro states, not realizing these are things we've invented and aren't physical in nature.
kgwgk 3 hours ago [-]
> Entropy is not a physical quantity, it is a measure of how far a system is from equilibrium.
That’s funny because the original thermodynamic entropy is defined only for systems in equilibrium.
42 minutes ago [-]
5 hours ago [-]
kgwgk 3 hours ago [-]
> Physical entropy governs real physical processes
> the measure is not the same thing as the phenomenon it describes.
There is some tension between those claims.
The latter seems to support the parent comment’s remark questioning whether a “fundamental physical interaction could follow from entropy”.
It seems more appropriate to say that entropy follows from the physical interaction - not to be confused with the measure used to describe it.
One may say that pressure is an entropic force and physical entropy governs the real physical process of gas expanding within a piston.
However, one may also say that it’s the kinetic energy of the gas molecules what governs the physical process - which arguably is a more fundamental and satisfactory explanation.
Good question. You are absolutely right that entropy is always fundamentally a way to describe are our lack of perfect knowledge of the system [0].
Nevertheless there is a distinct "reality" to entropic forces, in the sense that it is something that can actually be measured in the lab. If you are not convinced then you can look at:
So when viewed in this way entropy is not just a "made-up thing", but an effective way to describe observed phenomena. That makes it useful for effective but not fundamental laws of physics. And indeed the wiki page says that entropic forces are an "emergent phenomenon".
Therefore, any reasonable person believing in entropic gravity will automatically call gravity an emergent phenomenon. They must conclude that there is a new, fundamental theory of gravity to be found, and this theory will "restore" the probabilistic interpretation of entropy.
The reason entropic gravity is exciting and exotic is that many other searches for this fundamental theory start with a (more or less) direct quantization of gravity, much like one can quantize classical mechanics to arrive at quantum mechanics. Entropic gravity posits that this is the wrong approach, in the same way that one does not try to directly quantize the ideal gas law.
[0] Let me stress this: there is no entropy without probability distributions, even in physics. Anyone claiming otherwise is stuck in the nineteenth century, perhaps because they learned only thermodynamics but not statistical mechanics.
meindnoch 4 hours ago [-]
Sure, I'm not denying that entropy exists as a concept, that can be used to explain things macroscopically. But like you said, it's origins are statistical. To me, temperature is also a similar "made up" concept. We can only talk about temperature, because a sufficiently large group of particles will converge to a single-parameter distribution with their velocities. A single particle in isolation doesn't have a temperature.
So if they say gravity might be an entropic effect, does that mean that they assume there's something more fundamental "underneath" spacetime that - in the statistical limit - produces the emergent phenomenon of gravity? So it isn't the entropy of matter that they talk about, but the entropy of something else, like the grains of spacetime of whatever.
flufluflufluffy 2 hours ago [-]
Yes, exactly. The model is based on (in the first approach) a “lattice” of some type of undiscovered particle-like thing (what they refer to as “qubits” in the article, which is unfortunate because it is NOT the same “qubit” from quantum computing) permeating space time. Or maybe more aptly, it is that lattice from which spacetime emerges. And what we observe as the force of gravity emerges from the entropic forces happening in this lattice.
spacecadet 3 hours ago [-]
Im an idiot, let's get that out of the way first. I think that your temperature analogy answered your own question.
I guess my question in turn is, if we imagine a universe at the end of time(?), one that maybe dominated by a few black holes and not much else. Would an observer experience gravity if place sufficiently far enough way? Or even further, if nothing is left in the universe at all. Assuming that doesn't cause a big crunch, rip, or whatever...
simiones 3 hours ago [-]
> You are absolutely right that entropy is always fundamentally a way to describe are our lack of perfect knowledge of the system [0].
> [0] Let me stress this: there is no entropy without probability distributions, even in physics.
The second item doesn't entail the first. Probabilities can be seen as a measure of lack of knowledge about a system, but it isn't necessarily so. A phenomenon can also be inherently/fundamentally probabilistic. For example, wave function collapse is, to the best of our knowledge, an inherently non-deterministic process. This is very relevant to questions about the nature of entropy - especially since we have yet to determine if it's even possible for a large system to be in a non-collapsed state.
If it turns out that there is some fundamental process that causes wave function collapse even in perfectly isolated quantum systems, then it would be quite likely that entropy is related to such a process, and that it may be more than a measure of our lack of knowledge about the internal state of a system, and instead a measurement of the objective "definiteness" of that state.
I am aware that objective collapse theories are both unpopular and have some significant hurdles to overcome - but I also think that from a practical perspective, the gap between the largest systems we have been able to observe in pure states versus the smallest systems we could consider measurement devices is still gigantic and leaves us quite a lot of room for speculation.
IsTom 3 hours ago [-]
If you want to only have one possible past (i.e. can't destroy information) then when you end up in one branch of quantum state you need to "store" enough information to separate you form other branches and you really do need to have multiple possible microstates to differentiate them. If you look post-factum obviously you did end up in a specific state, but statistics do their work otherwise.
mjburgess 6 hours ago [-]
Even if we take that view, gravity is still basically a similar case. What we call "gravity" is really an apparent force, that isnt a force at all when seen from a full 4d pov.
Imagine sitting outside the whole universe from t=0,t=end and observing one whole block. Then the trajectories of matter, unaffected by any force at all, are those we call gravitational.
From this pov, it makes a lot more sense to connect gravity with some orderly or disorderly features of these trajectories.
Inertia, on this view, is just a kind of hysteresis the matter distribution of the universe has -- ie., a kind of remembered deformation that persists as the universe evolves.
tsimionescu 5 hours ago [-]
> From this pov, it makes a lot more sense to connect gravity with some orderly or disorderly features of these trajectories.
On the contrary, entropic gravity works pretty well for the Newtonian view of gravity as a force, and not the GR view of gravity as a deformation of space time and analogous to acceleration. Acceleration is a very elementary concept, one you find even in microscopic descriptions. Gravity being essentially the same thing makes it far more elementary than a concept like entropy, which only applies to large groups of particles.
So, if the GR picture is the right one, if gravity and acceleration are essentially the same thing, its very hard to see how that aligns with gravity being an emergent phenomenon that only happens at large scales. However, if gravity is just a tendency for massive objects to come together, as in the Newtonian picture, that is perfectly easy to imagine as an entropic effect.
whereismyacc 4 hours ago [-]
It sounds like you're talking about information entropy which to my understanding is analogue to but not the same as entropy in physics?
ajkjk 27 minutes ago [-]
It pretty much is the same, except that entropy in physics usually has a constant in front of it.
logicchains 6 hours ago [-]
Entropy isn't a function of imperfect knowledge. It's a function of the possible states of a system and their probability distributions. Quantum mechanics assumes, as the name implies, that reality at the smallest level can be quantised, so it's completely appropriate to apply entropy to describing things at the microscopic scale.
aurareturn 4 hours ago [-]
If we knew the exact state of all particles in an enclosed system, we can calculate what future states will be exactly. No need to calculate possible states.
IAmBroom 2 hours ago [-]
Since that's not possible in any physical system of one or more particles, it's irrelevant.
kgwgk 4 hours ago [-]
> Entropy isn't a function of imperfect knowledge. It's a function of the possible states of a system and their probability distributions.
There are no probability distributions over possible states when there is perfect knowledge of the state.
> Quantum mechanics
Entropy is also zero for a pure quantum state. You won’t have entropy without imperfect knowledge.
whereismyacc 4 hours ago [-]
> There are no probability distributions over possible states when there is perfect knowledge of the state.
I know very little about physics but I thought that the leading interpretations of quantum physics say that the probability distribution is all we can know about a system. The entropy is not due to due to a lack of information about the quantum state, but because the outcomes are inherently stochastic?
kgwgk 4 hours ago [-]
Entropy is about the state - not about “outcomes”.
“All we can know” is the precise state - at least in principle - and entropy is zero in that case.
mr_mitm 4 hours ago [-]
Just look at the definition of entropy. Knowledge about a system never enters the equation.
S := -k_B sum p_i ln (p_i)
ajkjk 25 minutes ago [-]
As the other replier said, despite your dismissiveness, the knowledge about the system is in the probabilities, so it's right there in the equation.
Suppose you flip a coin. Before flipping the coin, your knowledge is "heads or tails". After flipping it, your knowledge becomes one of either heads or tails. The amount of information you gained by resolving your imperfect knowledge is the entropy of the distribution.
The same model works for physical entropy without much modification; the imperfect knowledge is the difference between knowing a macrostate versus the exact microstate.
kgwgk 4 hours ago [-]
p_i
Edit to add lots of words:
In the definition of entropy
S := -k_B sum p_i ln (p_i)
knowledge about the system enters the equation in the p_i terms.
The other term is a constant so it’s not like there are many other choices to link the entropy to the system!
mr_mitm 4 hours ago [-]
Please communicate in full sentences with me.
I can only guess that your objection is something about probabilities. A microstate has a probability independent of my knowledge of the system just like the probability of having a royal flush doesn't change after drawing five cards. The probability of me ending the game with a royal flush might, but that is not what we mean by these probabilities.
kgwgk 3 hours ago [-]
The same microstate will have different probabilities depending on what are the constraints or measurements used in _your_ description of the system.
If you choose to describe the system using its microstate - and you know it - there are no probabilities anywhere.
You can of course know something and choose to ignore it - the entropy is still a reflection of the uncertainty (actual or for the sake of a lower-resolution model).
tsimionescu 3 hours ago [-]
But the point is that, regardless of how you choose to describe or even measure the system, it will need exactly as much heat to raise its temperature by 1 degree (or it will need as much kinetic energy to increase the average velocity of the constituents by the same amount, in the microstate framework). So there is some objective nature to entropy, it's not merely a function of subjective knowledge of a system. Or, to put it another way, two observers with different amounts of information on the microstate of a system will still measure it as having the same entropy.
kgwgk 1 hours ago [-]
There is some objective nature to the operational definition of entropy based on an experimental setup where you fix the volume and measure the temperature or whatever.
And this is related to the statistical mechanical definition of entropy based on the value of the corresponding state variables.
But it’s not a property of the microstate - it’s a property of the macrostate which makes sense only in the context of the experimental constraints and measurements.
If we relate entropy to work that can be extracted someone with a better understanding of the state of the system and operational access to additional degrees of freedom can extract additional work.
Thermodynamics assumes the state variables provide a complete description of the system. Statistical mechanics assumes the state variables provide an incomplete description of the system - and work out what that entails.
tsimionescu 21 minutes ago [-]
> But it’s not a property of the microstate - it’s a property of the macrostate which makes sense only in the context of the experimental constraints and measurements.
The same can be said about the wavefunction then, right? You can't directly observe it, you can only use it to predict the statistics of a particular experimental setup. So, at worse, entropy is as real as wavefunction amplitudes.
> If we relate entropy to work that can be extracted someone with a better understanding of the state of the system and operational access to additional degrees of freedom can extract additional work.
Is this actually true? Per my understanding, if I give you three containers, two of which are filled with some kind of gas that you know nothing about, and the third with a mix of those same gases, you can measure their entropy using thermodynamic experiments and tell which of the three is a mix of the other two because it will have a higher entropy. So, you can extract more work from one of the boxes despite not knowing anything more about it.
kgwgk 50 seconds ago [-]
> Per my understanding
What’s the source of that understanding? You cannot measure the entropy, only changes of entropy - which will be the same if I’m not mistaken.
mjanx123 4 hours ago [-]
Entropy is the opposite of potential
bmitc 3 hours ago [-]
> It's a made-up thing by humans.
All of physics is made up by humans.
6 hours ago [-]
cwharris 2 hours ago [-]
This seems backwards. Entropy is a dispersive force — it favors distribution and disorder. But the universe clumps. Planets, stars, galaxies — all of them are low-entropy configurations.
So how did scattered dust particles form the planet we’re standing on… through entropy?
If gravity is just emergent from entropy, then it should be fighting against planet formation, not causing it. There’s a missing piece here — maybe coherence, resonance, or field attraction. But “just entropy”? That doesn’t explain formation. It explains dissolution.
ajkjk 30 minutes ago [-]
There is a whole article explaining it... if you don't read the article, how do you expect to know the idea?
cantor_S_drug 37 seconds ago [-]
Actually Roger Penrose also had this line of thinking if my memory serves right.
heyjamesknight 35 minutes ago [-]
Entropy isn't a force. It doesn't "favor" anything. Its a property of statistics, information, and distributions.
Also why does this have that particular ChatGPT social media post rhythm to it?
Please, Lord, tell me we haven't reached the point where people are writing HN comments w/ AI.
But there are so many potential assumptions baked into these theories that it's hard to believe when they claim, "look, Einstein's field equations."
I agree.
> and that the global and exquisitly weak force of gravity emerges from that theory as a sort of accounting error.
Nah, it's probably just another weird family of bosons, just like the other forces.
From the article:
> Entropic gravity is very much a minority view. But it’s one that won’t die, and even detractors are loath to dismiss it altogether.
> FWIU this Superfluid Quantum Gravity [SQG, or SQR Superfluid Quantum Relativity] rejects dark matter and/or negative mass in favor of supervaucuous supervacuum, but I don't think it attempts to predict other phases and interactions like Dark fluid theory?
From https://news.ycombinator.com/item?id=43310933 re: second sound:
> - [ ] Models fluidic attractor systems
> - [ ] Models superfluids [BEC: Bose-Einstein Condensates]
> - [ ] Models n-body gravity in fluidic systems
> - [ ] Models retrocausality
From https://news.ycombinator.com/context?id=38061551 :
> A unified model must: differ from classical mechanics where observational results don't match classical predictions, describe superfluid 3Helium in a beaker, describe gravity in Bose-Einstein condensate superfluids , describe conductivity in superconductors and dielectrics, not introduce unoobserved "annihilation", explain how helicopters have lift, describe quantum locking, describe paths through fluids and gravity, predict n-body gravity experiments on earth in fluids with Bernoulli's and in space, [...]
> What else must a unified model of gravity and other forces predict with low error?
Seems pretty intuitive to me. The question remains though, what is this density made of since gravity exists in a vacuum? Quantum fluctuations popping in and out of reality? Does this infer that quantum fluctuations are affected by mass as well? It would seem so since in Bose Einstein Condensate, what is "communicating" the state across the BEC if the particles are no longer interacting?
OK, but it's nonsense. Apart from whatever-you're-talking-about-with-C, quantum fluctuations are not Brownian motion; Brownian motion is the visible effect of a lot of invisible particles interacting kinetically with macroscopic particles like dust, making those macroscopic particles appear to vibrate of their own accord. Atoms that cannot be seen in a microscope flying around in straight lines and randomly bumping into dust particles that can be seen.
https://en.m.wikipedia.org/wiki/Brownian_motion
So this is why warm objects weigh more?
https://herebeanswers.com/things-weigh-heavier-or-lighter-wh...
And gravity exists in a vacuum...
So I'm not talking strictly about particle interactions, that! Why I addressed this.
The key is C, constant speed and the random motion becoming more dense. The motion not the particles.
But we also know that's an approximation we tell kids, really life gets low entropy photons from the Sun, does it's thing, and then emits high entropy infrared waste heat. Energy is conserved, while entropy increases.
But where did the Sun got it's low entropy photons to start with? From gravity, empty uniform space has low entropy, which got "scooped up" as the Sun formed.
EDIT: not sure why this is downvoted, is the explanation Nobel Physics laureate Roger Penrose gives: https://g.co/gemini/share/bd9a55da02b6
"Solar energy at Earth is low-entropy because all of it comes from a region of the sky with a diameter of half a degree of arc."
also, from another reply:
"Sunlight is low entropy because the sun is very hot. Entropy is essentially a measure of how spread out energy is. If you consider two systems with the same amount of thermal energy, then the one where that energy is more concentrated (low entropy) will be hotter."
https://physics.stackexchange.com/questions/796434/why-does-...
Probably it's a bit of both. I'm not sure I understand your hypothesis about the Sun scooping up empty, low-entropy space. Wasn't it formed from dusts and gases created by previous stellar explosions, i.e. the polar opposite of low entropy?
https://g.co/gemini/share/bd9a55da02b6
"It's turtles all the way down."
The photons from Sun are hot, the space around Sun is cold, the system has a low entropy.
If the space around Sun was as hot as the photons, the entropy would be high.
We like placeholders for the unknown.
Pretty much anything known entered through such placeholder, it's just that equations could be connected more easily.
It's not like Higgs field is something you can directly observe
Phlogiston is the classic example. https://www.lesswrong.com/posts/RgkqLqkg8vLhsYpfh/fake-causa...
You find some un-identified variables.
Form some hypothesis, try to narrow it down.
Sometimes it is a discovery, new particle, and sometimes it is nothing.
But that is how science works.
At some point in time, everything was an unknown, and people had to work with unknowns.
This whole movement from the 'right' that all science has to know the answers ahead of time in order to justify spending money, is hindering progress. How can you know the results are worthwhile, in order to justify funding, before doing the research to know the results?
https://en.wikipedia.org/wiki/Casimir_effect
https://en.wikipedia.org/wiki/Zero-point_energy
https://en.wikipedia.org/wiki/Virtual_particle
https://en.wikipedia.org/wiki/Hawking_radiation
The gist of it is, that quantum mechanics prevents vacuum from really being empty. Any finite-size system or any system with some kind of influence/force/anything will have a lowest energy state that is not actually zero energy but slightly above. Which means that this non-zero can fluctuate and on occasion pair-produce and pair-annihilate particles (probability inversely depending on pair energy).
And yes, this sounds like some kind of ether...
Note that there are many very widely used physical theories that include mathematical elements that are not necessarily assigned any physical meaning. The Poynting vector in classical electrodynamics, for example, carries no widely accepted physical meaning, even though it appears in many well verified and used calculations. This doesn't make the theory suspect or anything, I'm not trying to imply that - simply that virtual particles being "real" or not is a mostly philosophical question that has no widely accepted consensus.
What is proven is that e.g. vacuum energy / zero point energy exists (not actually in the StarGate sense of extractable energy, just that the lowest energy state of any physical system isn't zero), and that the Casimir effect exists. Vacuum energy directly leads to virtual particles through pair production (which is a proven mechanism, at high energies, for low energies we do suspect that there isn't a cutoff there), and also influences e.g. high-energy cosmic rays leading to an observed high-energy cutoff (although there are other possible explanations for that cutoff and lack of very-high-energy cosmic rays). The Casimir effect is most easily explained by virtual particles and vaccum energy.
In Hawking radiation, the idea is actually that virtual particles through interaction with the gravity of the black hole become real particles. The event horizon actually makes those wave functions collapse such that real particles start to exist. Hawking radiation hasn't been observed yet, however.
[1] non-Kopenhagen QM has the same consequences, it's just even harder to explain actually.
OTOH de Broglie for one of the central ideas in the development of quantum mechanics: he inverted Einstein's idea about photons, which were previously thought to be waves but Einstein showed how they came in particle-like quanta. de Broglie realised you could apply the same thinking to matter, which had previously been thought of as particles, and describe them using waves. Subsequent observation of wavelike dynamics (diffraction) of electrons in the Davisson-Germer experiment got de Broglie the Nobel prize.
Similarly, umbrellas aren't places to stand under when it's not raining.
Now if there is "more space" around particle A, particle B will have a slightly higher statistical chance of randomly jumping closer to it, than farther.
Rinse-repeat. Gravity as we know it.
Does it? A single free particle won't "jump around randomly". Thermal motion is plain Newtonian motion with an extremely high rate of collisions. There's nothing random about it (let's put quantum things aside for now).
https://en.wikipedia.org/wiki/Georges-Louis_Le_Sage
Why?
Also how do you explain acceleration due to gravity with that model. How do you explain solid objects?
Repeating results in movement, getting closer to the object intensifies this effect, results in acceleration.
Solid objects are products of electric charge preventing atoms/particles from hitting each other, I dont think that has to have to do anything with gravity in this example?
E.g. if we have earth and moon:
Why is there more space from the moon towards earth than away?Like if you dropped the earth on a giant sheet, it would stretch the sheet more than what the moon would have.
Would this imply that cold objects have weaker gravity?
To me, entropy is not a physical thing, but a measure of our imperfect knowledge about a system. We can only measure the bulk properties of matter, so we've made up a number to quantify how imperfect the bulk properties describe the true microscopic state of the system. But if we had the ability to zoom into the microscopic level, entropy would make no sense.
So I don't see how gravity or any other fundamental physical interaction could follow from entropy. It's a made-up thing by humans.
Physical entropy governs real physical processes. Simple example: why ice melts in a warm room. More subtle example: why cords get tangled up over time.
Our measures of entropy can be seen as a way of summarizing, at a macro level, the state of a system such as that warm room containing ice, or a tangle of cables, but the measure is not the same thing as the phenomenon it describes.
Boltzmann's approach to entropy makes the second law pretty intuitive: there are far more ways for a system to be disordered than ordered, so over time it tends towards higher entropy. That’s why ice melts in a warm room.
Entropy isn’t always the driver of physical change, sometimes it’s just a map.
Sometimes that map is highly isomorphic to the physical process, like in gas diffusion or smoke dispersion. In those cases, entropy doesn't just describe what happened, it predicts it. The microstates and the probabilities align tightly with what’s physically unfolding. Entropy is the engine.
But other times, like when ice melts, entropy is a summary, not a cause. The real drivers are bond energies and phase thresholds. Entropy increases, yes, but only because the system overcame physical constraints that entropy alone can’t explain. In this case, entropy is the receipt, not the mechanism.
So the key idea is this: entropy’s usefulness depends on how well it “sees” the real degrees of freedom that matter. When it aligns closely with the substrate, it feels like a law. When it doesn't, it’s more like coarse bookkeeping after the fact.
The second law of thermodynamics is most “real” when entropy is the process. Otherwise, it’s a statistical summary of deeper physical causes.
So you can interpret entropy as being about as real as potential energy or newtons laws. Very useful for calculation, subject to evolution laws which are common across all systems - but potentially gives way as an approximation under a finer grained view (although the finer grained view is also subject to the same rules)
I'm a complete layman when it comes to physics, so forgive me if this is naive — but aren't "ordered" and "disordered" concepts tied to human perception or cognition? It always seemed to me that we call something "ordered" when we can find a pattern in it, and "disordered" when we can't. Different people or cultures might be able to recognize patterns in different states. So while I agree that "there are more ways for a system to be disordered than ordered," I would have thought that's a property of how humans perceive the world, not necessarily a fundamental truth about the universe
Check this Wikipedia article for a quick overview: https://en.wikipedia.org/wiki/Microstate_(statistical_mechan...
Details can be found in any textbook on statistical mechanics.
If the coins were of different color and you took that into account, then it wouldn't work.
It's not intuitive to me what gravity has to do with entropy though, as it's classically just a force and completely reversible (unlike entropy)? Ie if you saw a video of undisturbed objects only affected by gravity, you couldn't tell if the video was reversed.
[1] https://en.wikipedia.org/wiki/Entropy_in_thermodynamics_and_...
Because there are an infinite number of microstates (all the particles are interchangeable) that lead to the same macrostate: nothing happening for ever!
Further, it’s not objective: you’re choosing the basis which causes the complexity, but any particular structure can be made simple in some basis.
Maybe it would be more fitting to say that it just so happens that our human definition of “messy” aligns with entropy, and not that someone decided what messy atoms look like.
I’d say a bucket of water is more neat than a bucket of ice, macroscopically.
Ice melting is simply the water molecules gaining enough kinetic energy (from collisions with the surrounding air molecules) that they break the bonds that held them in the ice crystal lattice. But at the microscopic level it's still just water molecules acting according to Newton's laws of motion (forgetting about quantum effects of course).
Now, back on the topic of the article: consider a system of 2 particles separated by some distance. Do they experience gravity? Of course they do. They start falling towards the midpoint between them. But where is entropy in this picture? How do you even define entropy for a system of 2 particles?
The answer is that this doesn't happen in a system with only 2 particles. The idea of gravity as an entropic phenomenon is that you introduce some other kind of particle that permeates spacetime, so there is no system that only contains 2 particles. You may use some idea like virtual particles from quantum field theory, or you may define "quanta of space time" as something that is not technically a particle but basically works like one in a handwavy sense.
But the basic point of these entropy based theories is to explain gravity, and typcilaly spacetime itself, as an emergent result of a collection of numerous objects of some kind. This necessarily means that they don't make sense if applied to idealized systems with very few objects - which is why they typically posit such isolated systems simply can't actually exist in reality.
Explanation seems very rudimentary but that is the gist of the theory.
From my point of view, I might add the layer of information density. Every quantum fluctuation is an event and the more particles the more information is produced in a defined space volume. But there is no theory of information that is linked to the physics so ...that let me leave as that :).
Physical processes are "real", but entropy is a figment.
Entropy is not a physical quantity, it is a measure of how far a system is from equilibrium.
Lots of people talk about order/disorder or macro and micro states, not realizing these are things we've invented and aren't physical in nature.
That’s funny because the original thermodynamic entropy is defined only for systems in equilibrium.
> the measure is not the same thing as the phenomenon it describes.
There is some tension between those claims.
The latter seems to support the parent comment’s remark questioning whether a “fundamental physical interaction could follow from entropy”.
It seems more appropriate to say that entropy follows from the physical interaction - not to be confused with the measure used to describe it.
One may say that pressure is an entropic force and physical entropy governs the real physical process of gas expanding within a piston.
However, one may also say that it’s the kinetic energy of the gas molecules what governs the physical process - which arguably is a more fundamental and satisfactory explanation.
Nevertheless there is a distinct "reality" to entropic forces, in the sense that it is something that can actually be measured in the lab. If you are not convinced then you can look at:
https://en.wikipedia.org/wiki/Entropic_force
and in particular the example that is always used in a first class on this topic:
https://en.wikipedia.org/wiki/Ideal_chain
So when viewed in this way entropy is not just a "made-up thing", but an effective way to describe observed phenomena. That makes it useful for effective but not fundamental laws of physics. And indeed the wiki page says that entropic forces are an "emergent phenomenon".
Therefore, any reasonable person believing in entropic gravity will automatically call gravity an emergent phenomenon. They must conclude that there is a new, fundamental theory of gravity to be found, and this theory will "restore" the probabilistic interpretation of entropy.
The reason entropic gravity is exciting and exotic is that many other searches for this fundamental theory start with a (more or less) direct quantization of gravity, much like one can quantize classical mechanics to arrive at quantum mechanics. Entropic gravity posits that this is the wrong approach, in the same way that one does not try to directly quantize the ideal gas law.
[0] Let me stress this: there is no entropy without probability distributions, even in physics. Anyone claiming otherwise is stuck in the nineteenth century, perhaps because they learned only thermodynamics but not statistical mechanics.
So if they say gravity might be an entropic effect, does that mean that they assume there's something more fundamental "underneath" spacetime that - in the statistical limit - produces the emergent phenomenon of gravity? So it isn't the entropy of matter that they talk about, but the entropy of something else, like the grains of spacetime of whatever.
I guess my question in turn is, if we imagine a universe at the end of time(?), one that maybe dominated by a few black holes and not much else. Would an observer experience gravity if place sufficiently far enough way? Or even further, if nothing is left in the universe at all. Assuming that doesn't cause a big crunch, rip, or whatever...
> [0] Let me stress this: there is no entropy without probability distributions, even in physics.
The second item doesn't entail the first. Probabilities can be seen as a measure of lack of knowledge about a system, but it isn't necessarily so. A phenomenon can also be inherently/fundamentally probabilistic. For example, wave function collapse is, to the best of our knowledge, an inherently non-deterministic process. This is very relevant to questions about the nature of entropy - especially since we have yet to determine if it's even possible for a large system to be in a non-collapsed state.
If it turns out that there is some fundamental process that causes wave function collapse even in perfectly isolated quantum systems, then it would be quite likely that entropy is related to such a process, and that it may be more than a measure of our lack of knowledge about the internal state of a system, and instead a measurement of the objective "definiteness" of that state.
I am aware that objective collapse theories are both unpopular and have some significant hurdles to overcome - but I also think that from a practical perspective, the gap between the largest systems we have been able to observe in pure states versus the smallest systems we could consider measurement devices is still gigantic and leaves us quite a lot of room for speculation.
Imagine sitting outside the whole universe from t=0,t=end and observing one whole block. Then the trajectories of matter, unaffected by any force at all, are those we call gravitational.
From this pov, it makes a lot more sense to connect gravity with some orderly or disorderly features of these trajectories.
Inertia, on this view, is just a kind of hysteresis the matter distribution of the universe has -- ie., a kind of remembered deformation that persists as the universe evolves.
On the contrary, entropic gravity works pretty well for the Newtonian view of gravity as a force, and not the GR view of gravity as a deformation of space time and analogous to acceleration. Acceleration is a very elementary concept, one you find even in microscopic descriptions. Gravity being essentially the same thing makes it far more elementary than a concept like entropy, which only applies to large groups of particles.
So, if the GR picture is the right one, if gravity and acceleration are essentially the same thing, its very hard to see how that aligns with gravity being an emergent phenomenon that only happens at large scales. However, if gravity is just a tendency for massive objects to come together, as in the Newtonian picture, that is perfectly easy to imagine as an entropic effect.
There are no probability distributions over possible states when there is perfect knowledge of the state.
> Quantum mechanics
Entropy is also zero for a pure quantum state. You won’t have entropy without imperfect knowledge.
I know very little about physics but I thought that the leading interpretations of quantum physics say that the probability distribution is all we can know about a system. The entropy is not due to due to a lack of information about the quantum state, but because the outcomes are inherently stochastic?
“All we can know” is the precise state - at least in principle - and entropy is zero in that case.
S := -k_B sum p_i ln (p_i)
Suppose you flip a coin. Before flipping the coin, your knowledge is "heads or tails". After flipping it, your knowledge becomes one of either heads or tails. The amount of information you gained by resolving your imperfect knowledge is the entropy of the distribution.
The same model works for physical entropy without much modification; the imperfect knowledge is the difference between knowing a macrostate versus the exact microstate.
Edit to add lots of words:
In the definition of entropy
S := -k_B sum p_i ln (p_i)
knowledge about the system enters the equation in the p_i terms.
The other term is a constant so it’s not like there are many other choices to link the entropy to the system!
I can only guess that your objection is something about probabilities. A microstate has a probability independent of my knowledge of the system just like the probability of having a royal flush doesn't change after drawing five cards. The probability of me ending the game with a royal flush might, but that is not what we mean by these probabilities.
If you choose to describe the system using its microstate - and you know it - there are no probabilities anywhere.
You can of course know something and choose to ignore it - the entropy is still a reflection of the uncertainty (actual or for the sake of a lower-resolution model).
And this is related to the statistical mechanical definition of entropy based on the value of the corresponding state variables.
But it’s not a property of the microstate - it’s a property of the macrostate which makes sense only in the context of the experimental constraints and measurements.
If we relate entropy to work that can be extracted someone with a better understanding of the state of the system and operational access to additional degrees of freedom can extract additional work.
Thermodynamics assumes the state variables provide a complete description of the system. Statistical mechanics assumes the state variables provide an incomplete description of the system - and work out what that entails.
The same can be said about the wavefunction then, right? You can't directly observe it, you can only use it to predict the statistics of a particular experimental setup. So, at worse, entropy is as real as wavefunction amplitudes.
> If we relate entropy to work that can be extracted someone with a better understanding of the state of the system and operational access to additional degrees of freedom can extract additional work.
Is this actually true? Per my understanding, if I give you three containers, two of which are filled with some kind of gas that you know nothing about, and the third with a mix of those same gases, you can measure their entropy using thermodynamic experiments and tell which of the three is a mix of the other two because it will have a higher entropy. So, you can extract more work from one of the boxes despite not knowing anything more about it.
What’s the source of that understanding? You cannot measure the entropy, only changes of entropy - which will be the same if I’m not mistaken.
All of physics is made up by humans.
So how did scattered dust particles form the planet we’re standing on… through entropy?
If gravity is just emergent from entropy, then it should be fighting against planet formation, not causing it. There’s a missing piece here — maybe coherence, resonance, or field attraction. But “just entropy”? That doesn’t explain formation. It explains dissolution.
Also why does this have that particular ChatGPT social media post rhythm to it? Please, Lord, tell me we haven't reached the point where people are writing HN comments w/ AI.