Thermodynamic processes: probably easy question

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An ideal gas is compressed to 25% of its original volume in a thin-walled aluminum cylinder, raising questions about the thermodynamic process involved. The process is not isochoric due to the change in volume, and it is unlikely to be adiabatic since the compression occurs slowly, suggesting heat exchange. The discussion focuses on determining whether the process is isothermal or isobaric, with considerations about how the thin-walled container might affect pressure and thermal equilibrium. If the process were isobaric, the temperature of the gas would need to change to maintain constant pressure, which may not be feasible in this scenario. Ultimately, the key factors are the nature of the compression and the properties of the container influencing the gas behavior.
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Homework Statement



I'm probably over thinking this question.

An ideal gas is placed in a thin walled aluminum cylinder and slowly compressed to 25% of its original volume. The process is best described as adiabatic, isothermal, isochoric, or isobaric?

Homework Equations



none

The Attempt at a Solution



I know the difference between the different processes. I'm just not sure how the thin walled aluminum container adds to the problem or if it does. In similar problems, a thick walled aluminum container represented constant volume.

Obviously the answer is not isochoric since the volume changes. I don't think it is adiabatic because the process happens slowly.

That leaves isothermal and isobaric. I know isothermal must happen slowly enough so thermal equilibrium is maintained. (This is what I suspect is the answer).

How would a thin walled aluminum container affect pressure?
 
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Perhaps the wall thickness could affect the insulating ability of the container.

Hmmm, if you are basically deciding between isothermal and isobaric, then think about this: if it's isobaric, then what happens to the temperature of the gas upon compression in order to keep the pressure constant? Is it reasonable for this to happen?
 

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