I’ve always been under the impression that, although the math of information entropy and thermodynamic entropy are virtually identical, the two are completely independent of each other because they have entirely different physical significances. Kind of like how the math of F=m*a is the same as v=I*R, but voltage and mechanical force are very different things. Over in another thread I’ve been gently told that I don’t know what I’m talking about, which is fine but I want to understand why. Unfortunately I have no background in statistical mechanics, I’m just a BSME and, although I did well in thermo, StatMech gives me a migrane. But maybe someone can explain it so I can understand.
My working definitions:
Entropy is a state property of matter, expressed in units of Joules per kilogram-degree K. It is indicative of the availability of the heat energy of the substance to do work. The entropy of a substance can go up or down during any real process.
Total entropy is a property of thermodynamic systems, expressed in units of Joules per degree K. It is indicative of the reduction in the availability of the energy of the system to do work, as the result of a process. No real thermodynamic process can result in a negative total entropy. Changes in total entropy are also referred to as entropy generation.
Someone said this on the other thread:
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To put that information there or maintain it takes energy, hence a system elsewhere shows a corresponding increase in entropy...
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Just in case you're still listening Chile...  .... (the math is) the exact same thing...
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I thought that any increase in thermodynamic total entropy due to the action of putting the information into its media is due to those processes, which are outside of the system boundary of the media itself.
Let’s say that we’ve agreed that if I put a brick up on a shelf, it means one thing, but if I leave it on the floor it means another. The work done in raising the brick up to the shelf is completely reversible, so there’s no entropy generation between the brick on the floor and the brick on the shelf even though they encode very different information.
If I lift the brick and put it on the shelf, or alternatively lift the brick but let it drop back to the floor in such a manner that all of the irreversible losses are identical to putting it on the shelf, the total entropy is identical even though the encoded information is very different.
A similar comparison between a brick left on the floor and one that was raised and dropped back into position results in a difference in total entropy but no change in the encoded information.
So it seems to me that information and thermodynamic entropy have nothing to do with each other, aside from the fact that the mathematics is identical.
I’ve been under the impression that there are two ways to quantify “information”. One is due to the amount of it, as in how many bits it takes to encode. Given four colors you need a 2-bit binary, but then each color requires 2 bits to encode and so each has the same amount of information.
The other is due to the
meaning of the information, but that’s rather subjective which again means that it and thermo are independent of each other.
This is a good summary: “The point is that information "entropy" in all of its myriad nonphysicochemical forms as a measure of information or abstract communication has no relevance to the evaluation of thermodynamic entropy change in the movement of macro objects because such information "entropy" does not deal with microparticles whose perturbations are related to temperature.” (
http://www.entropysite.com/shuffled_cards.html)
So what am I missing?
I understood "the math" to be what "they're" referred; I certainly didn't intend to misrepresent what you said.
