This thread is to separate out that question from the, "Why a temperature differential.", thread.
The following appears to be Jack's original question.
I cross posted with him and would like to apologize, as it looks a little like I was responding to he, when in fact I was responding to another poster. I think Jack recognizes that. I won't rehash that here, as it's off topic. The apology and explanation was appropriate, and missing, so I'll put it here.Jack wrote: ↑Fri Jun 28, 2024 6:14 am To check my understanding of this. If a fluid is heated it will keep expanding until it reaches ambient temperatures again?
So assume you have two separate liters of fluid in a closed fully insulated space and you heat one up, you expand it until it reaches starting temperature again. Now you have one with a bigger volume than the other, the same temperature and pressure but lower density?
Jack I have no problems with you, please keep the questions coming. That response was for another poster. I recognize that you are here to help and understand. Maybe to teach others back home, too.
Okay, then let's continue. Jack's first question was actually two that are related :
"To check my understanding of this. If a fluid is heated it will keep expanding until it reaches ambient temperatures again?"
And:
"So assume you have two separate liters of fluid in a closed fully insulated space and you heat one up, you expand it until it reaches starting temperature again. Now you have one with a bigger volume than the other, the same temperature and pressure but lower density?"
The first one is posted as a statement, with a question mark at the end appearing to indicate that he wants to learn more if need be.
I would like to comment on that statement. Generally when a gas is expanded after heating has stopped, its temperature reduces from a process of adiabatic work. However, a few details need to be pointed out.
Expansion only happen if the system let's it. Merely heating a gas won't always lead to expansion. Case in point for any sealed tank, such as an oxygen or propane bottle, heating it will only raise the temperature and pressure, not the volume. The bottle constrains the gas to a constant volume. Constant volume means zero expression, or compression.
Of course the gas can have other expansion processes than adiabatic with work, since you've clarified, and specified an adiabatic with work expansion process, I will only explain that point.
You appear well aware that heating and adiabatic are opposites. So I won't bemoan that.
The second question seems to be setting up an experiment with one vessel space used as a 'control' and remaining at Tc ambient. And another that you have heated to Th. Then you have forced it to expand adiabatically with work until the gas is again back down to Tc. You now are asking what state it is in?
You make the correct point that it will have a larger volume and lower density. I agree. Much much lower density and larger volume. And lower pressure. Temperature back to Tc.
I supplied a couple of different ways to calculate that using gas laws. If you'd like, I would repost them here and explain them more simply. Mathematics is only learned if the explanation matches the person.
You have adequately asked a question and clarified it many ways. I hope this thread answers it more clearly, and allows more questions and pondering. Cary on men and women.