Isobaric, Isochoric, Isothermal, and Adiabatic Processes

In summary, the conversation discusses the process of going from state A to state F in an ideal gas, and the statements presented are analyzed to determine which ones are true. The discussion includes considerations of temperature, work, and heat flow, and ultimately concludes that Q provides energy input and is larger in magnitude than W.
  • #1
doggieslover
34
0
http://session.masteringphysics.com/problemAsset/1013990/12/1013990E.jpg

Which of the following statements are true about the first half of this process, just going from
state A to state F?

Both T and U increase.
W provides energy input.
Q provides energy input.
Q is larger (in magnitude) than W.

I know that Q provides energy input, but none of the other ones sound corrects to me. . .

please help.
 
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  • #2
OK. Here's how to approach this:

1) Is there an increase or decrease in temperature, and hence is there an increase or decrease in U? (Hint: Think ideal gas eqn.)
2) Is there any work done on or by the gas? How do you know?
3) Relate the signs and magnitudes of U and W, to the sign and magnitude of Q by the first law of thermodynamics.
 
  • #3
doggieslover said:
Which of the following statements are true about the first half of this process, just going from
state A to state F?

Both T and U increase.
W provides energy input.
Q provides energy input.
Q is larger (in magnitude) than W.
I will assume this is an ideal gas. The PV graph shows P declining linearly as V increases. Plot the isotherm (ie a path in which T is constant: ie P = nRT/V). Now what can you say about paths that are ABOVE the isotherm and paths that are below it (ie what happens to the temperature jn moving along the path?). Is A-F above or below the isotherm?

Now plot the adiabatic path:

[tex]PV^\gamma = K[/tex]

What can you say about Q on the adiabatic path? What can you say about a path that is above the adiabatic path? Below? Is A-F above or below the adiabatic path? What does that tell you about Q?'

Now consider the work done from A-F. How do you measure that? How does that compare to the work done with the adiabatic path? (Q=0). What does that tell you about the work done compared to heat flow?

AM
 

1. What is the difference between isobaric, isochoric, isothermal, and adiabatic processes?

Isobaric, isochoric, isothermal, and adiabatic processes are different types of thermodynamic processes that describe the change in a system's properties, such as temperature, pressure, and volume. The main difference between these processes lies in how these properties change during the process. In an isobaric process, the pressure remains constant, while in an isochoric process, the volume remains constant. In an isothermal process, the temperature remains constant, and in an adiabatic process, there is no exchange of heat with the surroundings.

2. What is an isobaric process and how does it work?

An isobaric process is a thermodynamic process in which the pressure of a system remains constant while the volume and temperature may change. This means that the system is allowed to expand or compress while maintaining a constant pressure. An example of an isobaric process is heating a gas in a container with a movable piston. As the gas is heated, its volume may increase, but the pressure remains constant due to the movable piston adjusting to maintain the pressure.

3. How does an isochoric process differ from an isobaric process?

An isochoric process is a thermodynamic process in which the volume of a system remains constant while the pressure and temperature may change. This means that the system is not allowed to expand or compress, and the volume remains constant. In contrast, in an isobaric process, the pressure remains constant, but the volume may change.

4. What is an isothermal process and how is it different from an adiabatic process?

An isothermal process is a thermodynamic process in which the temperature of a system remains constant while the pressure and volume may change. This means that the system is not allowed to expand or compress, and the temperature remains constant. In contrast, in an adiabatic process, there is no exchange of heat with the surroundings, meaning that the temperature may change as the system expands or compresses.

5. What are some real-life examples of adiabatic processes?

Some real-life examples of adiabatic processes include the compression and expansion of air in a bicycle pump, the compression of gas in a diesel engine, and the expansion of gas in a gas turbine. These processes are adiabatic because they occur quickly enough that there is no time for heat to be exchanged with the surroundings. The rapid compression or expansion causes a change in temperature, but the process is considered adiabatic as long as there is no heat transfer.

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