Confusion about the work done by an ideal gas

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Discussion Overview

The discussion revolves around the work done by an ideal gas in a piston system during rapid expansion against a constant external pressure. Participants explore the implications of non-quasistatic processes, the role of internal pressure, and the effects of piston mass on work calculations.

Discussion Character

  • Debate/contested
  • Technical explanation
  • Mathematical reasoning

Main Points Raised

  • One participant questions whether the work done by the gas is zero, arguing that if the internal pressure is zero, the piston would be compressed by external pressure.
  • Another participant suggests that the question hinges on whether the gas itself moves the piston or if another force is responsible for the piston movement, raising concerns about the speed of the piston relative to gas expansion.
  • A participant states that if the external pressure is constant and the piston moves quickly, the internal pressure must exceed the external pressure, indicating a non-quasistatic process where work done by the gas cannot be calculated.
  • It is proposed that when the piston is released, a dilatation region forms in the gas, with pressure equalizing to the external pressure, and that this phenomenon resembles a sound wave.
  • Another participant argues that for a massless piston, the work done by the gas can be calculated as the external pressure integrated over the change in volume, while also discussing scenarios involving a massive piston.

Areas of Agreement / Disagreement

Participants express differing views on the conditions under which work is done by the gas, particularly regarding the effects of piston mass and the nature of the expansion process. No consensus is reached on the calculations or implications of work done in this scenario.

Contextual Notes

Participants highlight the complexities of non-quasistatic processes and the influence of piston mass on work calculations, indicating that assumptions about pressure dynamics and system behavior are critical to the discussion.

theblackfish
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When an ideal gas,in a piston kind of system and whose equilibrium state is mentioned, is allowed to expand (piston is allowed to move and not gas leaking )against a constant external pressure very quickly, then, is the work done by gas zero or not zero ?

The argument for work being zero is that "the constituents take sometime to move towards the piston, as the piston moves away, and hence there's no pressure one the piston due to one side (inside ) and hence zero " I feel this argument is wrong because the pressure is 0 from the inside then the piston would be compressed by the external pressure.

Thank you in advance.
 
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I think the question is if the expanding gas moves the piston (for example the piston ist locked the gas pressure is increased e.g. by isochoric heating and then the piston is unlocked) or if another force moves the piston and the gas is expanded by the increase of available room.

theblackfish said:
"the constituents take sometime to move towards the piston, as the piston moves away, and hence there's no pressure one the piston due to one side (inside ) and hence zero "

Wouldn't that mean that the piston moves faster than the gas is expanded? I think theoretically that effect could maybe play a role when approaching the speed of sound. So I think that you are correct with your last statement, but where do you get the quoted statement from?
 
stockzahn said:
I think the question is if the expanding gas moves the piston (for example the piston ist locked the gas pressure is increased e.g. by isochoric heating and then the piston is unlocked) or if another force moves the piston and the gas is expanded by the increase of available room.
Wouldn't that mean that the piston moves faster than the gas is expanded? I think theoretically that effect could maybe play a role when approaching the speed of sound. So I think that you are correct with your last statement, but where do you get the quoted statement from?


Thats what my friends argued.
 
1. If the external pressure is constant, and you want to move the piston quickly, then there must be an internal pressure which is greater than the external pressure. This gives rise to a non-quasistatic process, which blows the piston outwards. In general, it is not possible to calculate the work done by the gas.
2. Zero work is done if the gas expands into a vacuum. This is also a non-quasistatic process.
 
When you release the piston, since the gas has inertia, a dilatation region begins to form in the gas immediately adjacent to the piston face. Within this region, assuming a massless piston, the pressure is virtually equal to the outside pressure (since the piston has no mass, it can accelerate at finite speed with even the slightest differential in pressure between inside and outside). As time progresses, the size of the dilatation region gets larger, and its leading edge travels backwards at the speed of sound within the gas (along the cylinder axis). So the phenomenon is similar to that of a sound wave.

In addition to this, there are viscous fluid stresses that develop within the gas that also contribute to the force per unit area exerted by the gas on the inside face of the piston. But, again, for a massless piston, Newton's third law tells us that the force exerted by the gas on the inside face of the piston must equal the constant external force exerted on the outside face of the piston.
 
Chandra Prayaga said:
1. If the external pressure is constant, and you want to move the piston quickly, then there must be an internal pressure which is greater than the external pressure. This gives rise to a non-quasistatic process, which blows the piston outwards. In general, it is not possible to calculate the work done by the gas.
This is not correct. If the piston is massless, the work done by the gas is equal to the external pressure integrated over the change in volume. If the piston has mass, and before the piston comes to rest, the work done by the gas is equal to the kinetic energy of the piston plus the integral of the external pressure over the volume change (up to that time); if the piston has come to rest, so that the gas is at thermodynamic equilibrium in its final state, then the work done by the gas is equal to the integral of the external pressure over the volume change (up to the end of the process). This all follows from a straightforward force balance on the piston.

The bottom line is that, if you can control the external pressure exerted on the piston, then you are automatically controlling the work done by the gas on the piston.
 
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