What Does Volume V Represent in Thermodynamics?

AI Thread Summary
The discussion focuses on the definition of volume (V) in thermodynamics, questioning whether it represents a fixed region containing all particles or the volume enclosed by the system's surroundings. It highlights the confusion around defining quantities like dV when considering systems that can change volume, such as an expanding box. The conversation also touches on the implications of having disconnected regions that cannot exchange particles or pressure, suggesting they should be treated as separate volumes. Additionally, it addresses the complexities of phase changes, particularly from gas to liquid along a container wall, and the need for a semi-open system to analyze these transitions. The importance of temperature and vapor pressure variations near the wall is emphasized, as these factors influence heat and mass transfer rates.
berra
Messages
20
Reaction score
0
I am confused over what the volume V stands for in thermodynamics.
Is it the smallest possible region of space containing all particles being studied? If so does it have to be connected?
Is it the volume enclosed by the surroundings of the system? If so, i thought the system was supposed to be fixed over time, but then why does one define quantities such as dV?
I hope you understand my confusion and can help me understand.
 
Last edited:
Science news on Phys.org
Usually, it is assumed that the fluid is constrained to be in some fixed volume - the interior of a box, for example. That volume can change (the box can expand for example).
If you have two disconnected regions, they cannot exchange particles and pressure, so it is better to treat them as two different volumes V1, V2.
 
I want to explore the phase shift from gas to liquid along the wall of a container (its cold outside it). I guess I would have to have a semiopen system then, since the liquid only arises on the wall. But then what is the volume of the system so I can look at the phase diagram and see if it has a phase change? (I was thinking of getting T and p from Navier Stokes)
 
You can consider a large chunk of gas, where the volume change due to condensation is negligible.
Common phase diagrams are p and T only.
 
berra said:
I want to explore the phase shift from gas to liquid along the wall of a container (its cold outside it). I guess I would have to have a semiopen system then, since the liquid only arises on the wall. But then what is the volume of the system so I can look at the phase diagram and see if it has a phase change? (I was thinking of getting T and p from Navier Stokes)

In the system you are considering, the temperature and water vapor partial pressure are not uniform within the container. Typically, there will be a thin boundary layer region near the wall in which the temperature varies rapidly from the bulk value for the chamber to the colder value at the wall, and in which the water vapor partial pressure varies rapidly from the bulk value for the chamber to the lower partial pressure value at the wall. Immediately at the wall, the water partial pressure is at the equilibrium value with the wall temperature. The rate of heat transfer from the bulk of the chamber to the wall depends on the thickness of the thermal boundary layer and temperature difference across the boundary layer, and the rate of water vapor mass transfer to the wall depends on the thickness of the concentration boundary layer and the vapor pressure difference across the boundary layer.
 

Thread 'Condensate rate of water for an air conditioning cooling coil'

I need to calculate the amount of water condensed from a DX cooling coil per hour given the size of the expansion coil (the total condensing surface area), the incoming air temperature, the amount of air flow from the fan, the BTU capacity of the compressor and the incoming air humidity. There are lots of condenser calculators around but they all need the air flow and incoming and outgoing humidity and then give a total volume of condensed water but I need more than that. The size of the...
View full post »
Thread 'Why work is PdV and not (P+dP)dV in an isothermal process?'

Thread 'Why work is PdV and not (P+dP)dV in an isothermal process?'

Let's say we have a cylinder of volume V1 with a frictionless movable piston and some gas trapped inside with pressure P1 and temperature T1. On top of the piston lay some small pebbles that add weight and essentially create the pressure P1. Also the system is inside a reservoir of water that keeps its temperature constant at T1. The system is in equilibrium at V1, P1, T1. Now let's say i put another very small pebble on top of the piston (0,00001kg) and after some seconds the system...
View full post »

Similar threads

I Why pressure stays the same when doubling both volume and temperature?
Replies
35
Views
4K
I Minimization of thermodynamic equilibrium
Replies
3
Views
2K
I Questions about my Understanding of Thermodynamics and Statistical Mechanics
Replies
2
Views
3K
I Change of Variables in Thermodynamics
Replies
4
Views
2K
I Concept of Thermal Equilibrium in the Context of Canonical Ensemble
Replies
5
Views
3K
Thermodynamic definition of volume
Replies
1
Views
1K
Partial derivatives of thermodynamic state functions
Replies
1
Views
2K
I How to know when a reversible process between end states exists?
Replies
12
Views
2K
I Understanding Wrev > Wirrev in Thermodynamics
Replies
17
Views
2K
I Sign convention on work done to a closed system containing gas
Replies
5
Views
3K

Hot Threads

Recent Insights

Back
Top