Isentropic Isolated Systems: Understanding the Entropy of the Universe

In summary: Additionally, the universe is constantly expanding and undergoing irreversible processes, which also indicate that it is not in equilibrium. Thermodynamics applies to systems in equilibrium, so it cannot be applied to the universe as a whole.
  • #1
vinven7
58
0
For a system that is completely isolated from its surroundings, basic thermodynamics requires that the quasi-static heat flux dQ and the entropy change dS be related by:
dQ = TdS
and since the system is isolated,
dQ=dS=0
Therefore, an isolated system should be isentropic, that is, it's entropy must remain a constant.

The UNiverse is itself an isolated system (please don't bring up branes and stuff like that, let's keep it classical) - so there is no heat input or output. Consequently, the entropy of the Universe should also be constant.
However, my understanding of the second law is that the entropy of the Universe is always increasing. Further, many cosmological models require that the entropy of the universe increase drastically immediately after big bang.

Can someone please explain if I am wrong somewhere and if so, how do I reconcile the two?
 
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  • #2
Your first sentence contains a very important word: quasi-static.
 
  • #3
jtbell said:
Your first sentence contains a very important word: quasi-static.

Could you please explain?
 
  • #4
Are all processes in the universe quasi-static?
 
  • #5
jtbell said:
Are all processes in the universe quasi-static?

If we are talking about the Universe as a whole and treat it as our system, why would the processes within the system matter at all? Please correct me if I am wrong
 
  • #6
vinven7 said:
If we are talking about the Universe as a whole and treat it as our system, why would the processes within the system matter at all? Please correct me if I am wrong

You are wrong because you assume that entropy can't be made. Entropy can and is made all the time by irreversible processes.

The processes inside the system can make entropy. If a system is isolated, then the entropy can not be moved out of the system. However, the system can still make entropy.

Entropy is an intensive property. Therefore, every bit of entropy is located somewhere in space. There is an entropy density describing how the density is distributed in space. The entropy density at any location can be changed either by moving entropy or by making it.



The second law of thermodynamics only says that entropy can't be destroyed. However, there is no law that says that entropy can't be made. There is no law that says that entropy can't be moved. The "trick" in many thermodynamic problems is distinguishing one from the other.

There are two things that a process can do with entropy: move it or make it. A lot of confusion comes about because people don't realize there are two options. So when the entropy of a system changes, it is one of the two options. Move it or make it.

There are two important types of process that are defined in terms of what they do to the entropy in a closed system. An adiabatic process can make entropy in a closed system, but it often doesn't move entropy in or out of the closed system. An isothermal process can move entropy in or out of the system, but it often doesn't make entropy.

There are two processes that are defined on what they do to total entropy. An irreversible process is by definition a process that makes entropy. A reversible process by definition a process that doesn't make entropy.
 
  • #7
Thanks so much! That cleared my confusion
 
  • #8
vinven7,
in order to find out what happens to entropy, one must first define what it is. In thermodynamics, change of entropy is defined by integral

[tex]
\Delta S = \int_1^2 \frac{dQ}{T}
[/tex]

where the integration is over trajectory in space of quasistatic states. The entropy is then function of the upper bound of the integral, or in other words, of the state variable.

But it is difficult to define heat and state variables for Universe. The Universe does not seem to be in equilibrium. So the thermodynamics definition of entropy does not seem to be applicable.
 
  • #9
For an irreversible processes that takes place in a closed system, Clausius inequality states that

dS > dQ/T

where dQ and T represent the heat inflow and the corresponding temperature, respectively, at the boundary of the system. For the universe, which represents an isolated system, dQ = 0, so that dS > 0.
 
  • #10
Chestermiller said:
For an irreversible processes that takes place in a closed system, Clausius inequality states that

dS > dQ/T

where dQ and T represent the heat inflow and the corresponding temperature, respectively, at the boundary of the system. For the universe, which represents an isolated system, dQ = 0, so that dS > 0.

Thank you. This is awesome. In strict thermodynamic terms, how do we show that the universe is not an equilibrium system?
 
  • #11
Chestermiller,

the Clausius inequality applies to quasistatic process which creates entropy in the system. In order to call a process quasistatic, one has to have macroscopic quantities to define the state of the system and change them slowly.

What quantities should we use for macroscopic state of the Universe?

It does not make sense to apply thermodynamics in this naive way to whole Universe. Thermodynamics is about control of few variables and about equilibrium properties between them - and for Universe, this is out of question.
 
  • #12
vinven7 said:
Thank you. This is awesome. In strict thermodynamic terms, how do we show that the universe is not an equilibrium system?

A system in equilibrium is (macroscopically) unchanging in time, by definition. Pressure, temperature, etc. are all unchanging in time. Since we know things are changing in time, we know that the universe is not an equilibrium system.
 
  • #13
Rap said:
A system in equilibrium is (macroscopically) unchanging in time, by definition. Pressure, temperature, etc. are all unchanging in time. Since we know things are changing in time, we know that the universe is not an equilibrium system.

By this definition the Earth moving around the sun cannot be an equilibrium system - can it? If we assume that there was only the sun and the Earth (leave everything else out)
 
  • #14
When we talk about the "universe" in a thermodynamic sense, what we are really referring to is an isolated system which is comprised of two parts: a "system" portion plus a "surroundings" portion. The "system" plus the "surroundings" add up to what we call the "universe." But this only a sub-region of the actual UNIVERSE that the astrophysicists refer to. Still, the actual UNIVERSE is continually undergoing irreversible processes and, in the end, when it does reach thermodynamic equilibrium, its entropy will be greater than when it started.

I also want to add that the Clausius inequality does not refer to closed systems undergoing quasistatic processes, but rather to systems undergoing irreversible processes (which are not quasistatic). I also want to point out that the mathematical form in which the Clausius inequality typically appears is very imprecise. A more precise form is to say that, if B represents the boundary surface of a closed system that is undergoing an irreversible change from thermodynamic equilibrium state 1 to thermodynamic equilibrium state 2, and if we calculate the integral over time and over the surface B of the normal component of the inwardly directed heat flux divided by the local temperature at the surface, this integral will be less than the change in entropy for the system contained within B.
 
  • #15
vinven7 said:
By this definition the Earth moving around the sun cannot be an equilibrium system - can it? If we assume that there was only the sun and the Earth (leave everything else out)

That's an interesting question. For the case of the sun and the earth, the sun is not in equilibrium, it will burn up its fuel to a point where it becomes a red giant, etc. But suppose we had two iron balls orbiting each other. Unless they were at zero K, they would evaporate iron and so they are not in equilibrium, but I don't know what the final equilibrium state would be. If they were at zero K, I think there would still be "tidal forces" which would distort the balls, heating them up, causing the rate of rotation to decrease, and bringing them closer, so even that would not be equilibrium. I'm not sure if maybe the balls were rotating on their axes at just the right angular velocity, you could make the tidal forces not have a heating effect.

(Edit) - thinking about it, even if the tidal forces could be eliminated as a source of heating, there would be dissipation of energy by gravitational waves, and there would be no way around that. A single spinning iron ball at zero K would not emit gravitational waves, but then its angular momentum would just be part of its thermodynamic internal energy, so I guess the idea that thermal equilibrium is that all macro parameters are constant in time is still valid.

Chestermiller said:
I also want to add that the Clausius inequality does not refer to closed systems undergoing quasistatic processes, but rather to systems undergoing irreversible processes (which are not quasistatic).

Is that true? I mean, if you have a container of stoichiometric hydrogen and oxygen at room temperature, if you don't explode it, the reaction to H2O will proceed slowly (quasistatically) and it's irreversible.
 
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  • #16
Good morning vinven7,

I think your difficulty arises from a basic misconception, that Chestermiller has touched upon.

You observe that the universe is an isolated system, then try to apply dQ.

By definition of an isolated system dQ = 0. Period.

Remember that Q is the heat flux across the boundary, not the flux within parts of the system.
The energy of an isolated system is constant.
The entropy of an isolated system either remains constant or increases, it cannot decrease.

As regards the universe it is either infinite in which case the entropy is infinite. What does it mean to say that infinity is increasing or constant?

Or the universe is finite in which case the simple statements above apply.

Do you understand the proof that the entropy of an isolated system must increase or be constant?
 
  • #17
Rap said:
Is that true? I mean, if you have a container of stoichiometric hydrogen and oxygen at room temperature, if you don't explode it, the reaction to H2O will proceed slowly (quasistatically) and it's irreversible.

Let me restate what I said a little more precisely: The Clausius inequality does not refer to closed systems undergoing exclusively quasistatic processes, but rather to systems undergoing irreversible processes (which are not restricted to being quasistatic). My point is that the key word here is "irreversible," not "quasistatic."
 
  • #18
Studiot said:
Good morning vinven7,

By definition of an isolated system dQ = 0. Period.

Studiot, I think you also meant to say that an isolated system is closed, so that no mass enters or leaves the system (dm = 0).
 
  • #19
Studiot, I think you also meant to say that an isolated system is closed, so that no mass enters or leaves the system (dm = 0).

Perfectly true but I'm not sure I needed to say that.

An isolated system is one in which nothing, neither energy (whether in the form of heat or work or whatever) nor matter (mass) crosses the boundary.

A closed system is one in which energy (work ,heat etc) may be transferred across the boundary but matter (mass) may not.

So, of necessity an isolated system is also a closed one.
 
  • #20
Studiot said:
Perfectly true but I'm not sure I needed to say that.

An isolated system is one in which nothing, neither energy (whether in the form of heat or work or whatever) nor matter (mass) crosses the boundary.

A closed system is one in which energy (work ,heat etc) may be transferred across the boundary but matter (mass) may not.

So, of necessity an isolated system is also a closed one.

I'm not sure you needed to say that either. Still, when you were talking specifically about the definition of an isolated system, I though it might be worth mentioning. No big deal.
 
  • #21
Let me restate what I said a little more precisely: The Clausius inequality does not refer to closed systems undergoing exclusively quasistatic processes, but rather to systems undergoing irreversible processes (which are not restricted to being quasistatic). My point is that the key word here is "irreversible," not "quasistatic."

I understand your point; this is how the inequality is usually derived, for irreversible process. However, I think the process still has to be quasi-static as well. This is because we refer to entropy. Entropy is a function of macroscopic state (defined by U, V...). To a state which is not described by such set of values (non-equilibrium state), there is no way to ascribe entropy. Or is there?

This seems to be the case with the Universe; what macroscopic variables would you choose to describe its state?
 
  • #22
Jano L. said:
I understand your point; this is how the inequality is usually derived, for irreversible process. However, I think the process still has to be quasi-static as well. This is because we refer to entropy. Entropy is a function of macroscopic state (defined by U, V...). To a state which is not described by such set of values (non-equilibrium state), there is no way to ascribe entropy. Or is there?

This seems to be the case with the Universe; what macroscopic variables would you choose to describe its state?

For entropy, the only two states that matter are the initial and final equilibrium states. These two states determine the change of entropy. There are an infinite number of paths that the system take to get from the initial to the final equilibrium state. These paths do not need to be quasi-static. If the path between the initial and the final state is reversible, then the heat flow entering through the boundary divided by the temperature at the boundary (integrated over time) will equal the change in entropy between the initial and final equilibrium states. If the path between the initial and the final state is irreversible, then the heat flow entering through the boundary divided by the temperature at the boundary (integrated over time) will be less than the change in entropy. The change in entropy provides an upper bound to the integral of the heat flow entering through the boundary divided by the temperature at the boundary, over all possible paths.
 
  • #23
For entropy, the only two states that matter are the initial and final equilibrium states.
Of course. However, is Universe in equilibrium state?
 
  • #24
Jano L. said:
Of course. However, is Universe in equilibrium state?
According to most scientists, the observable universe is not in an equilibrium state. The observable universe can't be in an equilibrium state because it is expanding.

The universe started in a high density, high temperature and low entropy state. The universe in this state is commonly referred to as the Big Bang. As time goes on, it is asymptotically approaching a zero density, zero temperature and high entropy state. This asymptotic limit is often referred to as the Heat Death.

Entropy is a well defined quantity even in a non equilibrium state. However, it is defined in terms of a hypothetical series of reversible transitions.

The Zeno "paradox" seems to have resurfaced yet again. The OP has given an argument that entropy can't be increasing because any irreversible process can be broken up into a series of reversible processes. The argument is formally similar to the argument that nothing can move because each motion can be broken up into a series of not moving steps. This argument against motion was used by the classical Greek philosopher, Zeno. He was trying to prove that logic isn't sufficient in analyzing the real world.

The thermodynamics argument formally maps onto Zeno's paradox because on a subatomic level, all irreversible processes occur due to the motion of particles.

Lots of work has been done on resolving "Zeno's" paradox. Whether you except these "resolution arguments" is up to you. However, I will rephrase Zeno's paradox in terms of thermodynamics.

Any irreversible process lasting a finite amount of time can be broken down into an infinite series of reversible processes each lasting an infinitesimal amount of time. "Infinitesmal time" means "in the limit of zero time". Since each step is reversible, there should be no such thing as an irreversible process.

"Irreversible processes occur" despite this argument. Therefore, one can claim that logic doesn't work in thermodynamics. However, I present two argument against this conclusion.

"Infinitesimal time" is not the same as "zero time". An "infinitesmal time" is a hypothetically "the limit" as the time approaches zero. The mathematical meaning of "limit" has been analyzed extensively since the time of Zeno. "Limits" are mathematical and logically defined and analyzed. "Being "the limit" is not mathematically the same as "being equal to". So an infinite series of "infinitesimal processes" can add up to a "finite process" using strict mathematical formalism.

Another argument for logic is that energy and momentum is quantized according to quantum mechanics. Therefore, there really is no such thing as an "infinitesimal reversible process".

Both arguments are anti-intuitive to many people. The last is really a cheat since no self consistent quantum mechanical theory has been found consistent with astronomical observations. However, I am done if you agree that the problem is a modified version of Zeno's paradox.

I think an in depth discussion of Zeno's paradox would within forum guidelines as long as it took place in the mathematics part of the forum. There are a whole bunch of scientific problems that can be mapped onto Zeno's paradox. Some people reject biological evolution on the basis of Zeno's paradox. We see here that someone has a problem with thermodynamics due to Zeno's paradox. Since practically every branch of science uses the mathematical concept of "limit", Zeno's paradox can turn up anywhere.

So the problem is the concept of limit, not with thermodynamics.
 
  • #25
There are several Zeno paradoxes.

The resolution of the one about the semidistance relies on the limit

[tex]\mathop {\lim }\limits_{n \to \infty } \frac{1}{{2n}} = 0[/tex]

Which leads to the sum

[tex]\sum\limits_1^\infty {\frac{1}{{2n}}} = 1[/tex]

What particular limit are you referring to?
 
  • #26
Studiot said:
There are several Zeno paradoxes.

The resolution of the one about the semidistance relies on the limit

[tex]\mathop {\lim }\limits_{n \to \infty } \frac{1}{{2n}} = 0[/tex]

Which leads to the sum

[tex]\sum\limits_1^\infty {\frac{1}{{2n}}} = 1[/tex]

What particular limit are you referring to?
I am talking about the limit corresponding to the distance an arrow travels, or the one about Achilles and the tortoise.

I am not sure what the corresponding mathematical expressions are.

In any case, obviously entropy is increasing in the universe. The universe is "quasistatic" only over very small time intervals. It is not static.

The sum of a large number of short interval irreversible processes is an irreversible process. A short
 
  • #27
Any irreversible process lasting a finite amount of time can be broken down into an infinite series of reversible processes each lasting an infinitesimal amount of time.

This is not true, if we want to use the words reversible and irreversible in their standard meaning in thermodynamics. Thermodynamically irreversible process cannot consist of thermodynamically reversible processes. It can only consist of microscopically reversible processes, but this is irrelevant, since there is no entropy on the microscopic level of description. I do not see any connection to Zeno paradox here.

The universe is "quasistatic" only over very small time intervals. It is not static.

The term "quasistatic process" does not only mean that the process is slow. It requires that the process be a sequence of states very close to thermodynamic equilibrium. Now observed part of the Universe is not in such equilibrium as a whole; its state is not described by few thermodynamic parameters.

If we want to talk about entropy of Universe, we have to define it first, and the standard sdefinition [itex]\Delta S(1~to~2) = \int_1^2 \frac{dQ}{T}[/itex] does not apply for the Universe; there is no 1 or 2 and there is no [itex]T[/itex].
 
  • #28
Hello Jano, why can Darwin not use the other standard definition of entropy?

S(E,V,N,α) = k lnΩ(E,V,N,α)
 

What is an isentropic isolated system?

An isentropic isolated system is a thermodynamic system that experiences no change in entropy, meaning that there is no net transfer of heat or work within the system. This type of system is often used in theoretical models to better understand the behavior of real-world systems.

How does understanding the entropy of the universe relate to isentropic isolated systems?

The concept of entropy, which is a measure of the disorder or randomness in a system, is closely related to the idea of isentropic isolated systems. By studying and understanding the entropy of the universe, scientists can gain insights into how energy and matter are distributed and how they interact within isolated systems.

Why is the entropy of the universe often referred to as "the arrow of time"?

The entropy of the universe plays a crucial role in the concept of time. As the universe expands and energy becomes more dispersed, the overall entropy increases. This means that the universe is constantly moving towards a state of maximum disorder and randomness, which is often associated with the forward movement of time.

What are the implications of understanding the entropy of the universe for our understanding of the origins of the universe?

Studying and understanding the entropy of the universe can provide important insights into the origins of the universe. The second law of thermodynamics states that the entropy of a closed system will always increase over time. By tracing the increasing entropy of the universe backwards, scientists can gain a better understanding of how the universe may have originated.

Are there any practical applications of studying isentropic isolated systems and the entropy of the universe?

While the study of isentropic isolated systems and the entropy of the universe may seem purely theoretical, there are many practical applications. This knowledge can be applied in fields such as cosmology, thermodynamics, and even information theory. Understanding these concepts can also lead to advancements in technology, such as more efficient energy systems and improved models for predicting climate change.

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