The Ideal Gas Law and Temperature Changes

In summary, a cylinder containing gas at 300 K is divided into two parts, A and B, of equal volume by a frictionless piston, with each part having a volume of 100 cm3 and equal initial pressure. The temperature of the gas in part A is raised to 373 K while part B is maintained at the initial temperature. Using the ideal gas law, and knowing that the pressure and volume of the gas are equal in both chambers, we can determine that the total volume of the gas remains constant and the pressure in chamber B stays the same. The distance moved by the piston can then be calculated using the equation W = -pAΔx.
  • #1
nbasma20
4
0
A cylinder containing gas at 300 K is divided into two parts, A and B, of equal volume by a frictionless piston of cross-sectional area of 15 cm 2. Each part has a volume of 100 cm 3 and equal initial pressure. The temperature of the gas in part A is raised to 373 K, while the part B is maintained at the original temperature. The piston and walls are perfect insulators. Calculate
how far will the piston move due to the change in temperature.
 
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  • #2
Hi nbasma20. Welcome to Physics Forums.

In order to get help here you should follow the suggested post outline, including what you feel are equations relevant to your problem, and your own attempt at a solution (or at least the things you've tried so far).

So what are your thoughts on how to approach the problem? What laws do you think might be applicable?
 
  • #3
Not sure at all.

I suppose the distance moved by the piston can be worked out from

W = - p A dx

But how to calculate W?

I have no idea where to begin.
 
  • #4
Have you looked at the ideal gas law and how it might be of use?

The piston is apparently massless, and it's free to move if there's a force differential. What does that tell you about the pressure in both chambers?
 
  • #5
We know that the initial pressure is equal in each part.

And how can I make use of pV = nRT?

Thanks
 
  • #6
nbasma20 said:
We know that the initial pressure is equal in each part.

And how can I make use of pV = nRT?

Thanks

Just the initial pressure? Think about it. How would a pressure difference be maintained if the piston is free to move?

PV = nRT applies to gasses! You've got gas in both chambers, and more than that, you know that here is an equal amount of gas in each chamber (n is the same). Further, they are starting with the same volume, pressure, and temperature. What about the total volume of the gas (sum of the volumes of each chamber)?

If the gas in chamber B is being maintained at the initial temperature, what does that say about the product P*V for that chamber?
 

FAQ: The Ideal Gas Law and Temperature Changes

What is thermodynamics?

Thermodynamics is the branch of physics that deals with the relationships between heat, work, temperature, and energy. It studies how energy is transferred and transformed in systems, and how these processes affect the properties of matter.

What are the three laws of thermodynamics?

The first law states that energy cannot be created or destroyed, only transferred or converted from one form to another. The second law states that the total entropy of a closed system will always increase over time. The third law states that the entropy of a pure, perfect crystal at absolute zero temperature is zero.

How is thermodynamics applied in real life?

Thermodynamics has many practical applications, including designing engines, refrigeration systems, and power plants. It is also used in fields such as chemistry, biology, and materials science to understand and optimize chemical reactions, metabolism, and material properties.

What is the difference between heat and temperature?

Temperature is a measure of the average kinetic energy of particles in a substance, while heat is the transfer of energy from a hotter object to a colder one. In other words, temperature is a property of a substance, while heat is a process of energy transfer.

Can the laws of thermodynamics be violated?

No, the laws of thermodynamics are fundamental principles of nature and have been extensively tested and confirmed through experiments. They apply to all systems in the universe, from tiny particles to the entire universe, and cannot be violated.

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