What Does Function of State Mean in Thermodynamics?

In summary: Would you be able to do that? If so, congratulations, you understood what it means to solve for an equation of state. If not, read on.The example I gave with potential energy and the interpretation of it you've given are still acceptable ways to think about what is meant by an "equation of state". The takeaway, though, is that an equation of state describes a quantity that doesn't care about the methods by which it reached its current state.
  • #1
KingDaniel
44
1

Homework Statement



I read the following in my Thermodynamics study notes from university but I don't quit fully understand it. Please explain this to me in layman's terms:

"U is a "function of state", and is thus a property of the system. Although ΔU is defined, Q and W cannot be separately calculated from knowledge of the initial and final states alone".

What does "function of state" mean? Also, please explain the rest of the quote.

Homework Equations



ΔU = Q + W[/B]

The Attempt at a Solution

 
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  • #2
KingDaniel said:

Homework Statement



I read the following in my Thermodynamics study notes from university but I don't quit fully understand it. Please explain this to me in layman's terms:

"U is a "function of state", and is thus a property of the system. Although ΔU is defined, Q and W cannot be separately calculated from knowledge of the initial and final states alone".

What does "function of state" mean? Also, please explain the rest of the quote.

Homework Equations



ΔU = Q + W[/B]

The Attempt at a Solution


To say that the potential energy U of a system is a "function of state" is to say that the value of U doesn't depend on the way in which the system's current state was arrived. In other words, you can relate it to potential energy changes in conservative fields. If you've already taken any course covering classical mechanics, you should know that the change in potential energy of an object in a gravitational field is path independent; it only cares about initial and final position. However, the total work done by someone (not the field) in moving said object in the gravitational field is path dependent and cannot be found with certainty by only looking at the initial and final positions of the object. Does that help?
 
  • #3
Kinta said:
To say that the potential energy U of a system is a "function of state" is to say that the value of U doesn't depend on the way in which the system's current state was arrived. In other words, you can relate it to potential energy changes in conservative fields. If you've already taken any course covering classical mechanics, you should know that the change in potential energy of an object in a gravitational field is path independent; it only cares about initial and final position. However, the total work done by someone (not the field) in moving said object in the gravitational field is path dependent and cannot be found with certainty by only looking at the initial and final positions of the object. Does that help?
In the context that the OP is using, U is not potential energy. It is thermodynamic internal energy.
 
  • #4
@Kinta , it makes sense when I think about it in the context of potential energy...because say for example, the Work done in moving a block directly vertically up to a certain point would be different (greater) than the Work done in sliding the same block up a ramp to the same height. This is because the Work done depends on the "distance moved by the point of application of the force in the direction of the force", right?
However, please try to put it in thermodynamics context. @Chestermiller , please help too
 
  • #5
Also, if something is a "function of state" doesn't it mean that it it depends on the current state?
 
  • #6
Chestermiller said:
In the context that the OP is using, U is not potential energy. It is thermodynamic internal energy.

You're right, @Chestermiller. I let my analogy get a little too far ahead of me and lost sight of the context.

KingDaniel said:
@Kinta , it makes sense when I think about it in the context of potential energy...because say for example, the Work done in moving a block directly vertically up to a certain point would be different (greater) than the Work done in sliding the same block up a ramp to the same height. This is because the Work done depends on the "distance moved by the point of application of the force in the direction of the force", right?
However, please try to put it in thermodynamics context. @Chestermiller , please help too

The example I gave with potential energy and the interpretation of it you've given are still acceptable ways to think about what is meant by an "equation of state". The takeaway, though, is that an equation of state describes a quantity that doesn't care about the methods by which it reached its current state.

To put this in the context of your original post, imagine the following situation. Let's say I show you some gas in a container that is both compressible and temperature-variable (i.e., the container can be heated to add heat to the gas). By some sort of wizardy, I've ascertained the gas's thermal internal energy and I share that information with you. Now I tell you to leave the room and come back in about 5 minutes. When you come back, I inform you that the internal energy of the gas has changed by some known amount so that we have a value for the change in internal energy. If you're then asked, "By what method was the increase in thermal internal energy of the gas attained?", you'd be unable to give a certain answer because you wouldn't know if the gas was compressed or heated, but you'd still know the change in internal energy of the gas.
 
  • #7
KingDaniel said:
@Kinta , it makes sense when I think about it in the context of potential energy...because say for example, the Work done in moving a block directly vertically up to a certain point would be different (greater) than the Work done in sliding the same block up a ramp to the same height. This is because the Work done depends on the "distance moved by the point of application of the force in the direction of the force", right?
Wrong. If the ramp is frictionless, the amount of work is the same. The distance is larger but the force is less. Their product is the same.
However, please try to put it in thermodynamics context. @Chestermiller , please help too
Please see my discussion of this topic in the Physics Forums insight article I wrote: https://www.physicsforums.com/insights/understanding-entropy-2nd-law-thermodynamics/. Even though the title implies the 2nd law of thermodynamics, there is key discussion of the 1st law. The article addresses the very questions that you are asking.

Chet
 
Last edited:

FAQ: What Does Function of State Mean in Thermodynamics?

What is thermodynamics?

Thermodynamics is the branch of physics that deals with the relationships between heat, work, energy, and temperature. It studies the behavior of systems at the macroscopic scale and how energy is transferred between them.

What are the laws of thermodynamics?

The laws of thermodynamics are fundamental principles that govern the behavior of energy and matter in a system. The first law states that energy cannot be created or destroyed, only transferred or converted. The second law states that the total entropy of a closed system will always increase over time. The third law states that the entropy of a perfect crystal at absolute zero temperature is zero.

What is the difference between heat and temperature?

Heat is a form of energy that is transferred between objects or systems due to a temperature difference. Temperature, on the other hand, is a measure of the average kinetic energy of the particles in a system. In other words, heat refers to the transfer of energy, while temperature is a measure of the amount of energy in a system.

How does thermodynamics relate to everyday life?

Thermodynamics plays a crucial role in our everyday lives. It explains how engines and refrigerators work, how food is cooked, how buildings are heated and cooled, and even how our bodies maintain a constant temperature. Understanding thermodynamics can also help us make more efficient use of energy and resources.

What are some real-world applications of thermodynamics?

Some real-world applications of thermodynamics include the design and optimization of engines, refrigeration systems, air conditioning systems, power plants, and chemical processes. It is also used in the study of meteorology, oceanography, and the behavior of stars and galaxies. Additionally, thermodynamics is essential in the development of new materials and technologies, such as solar cells and batteries.

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