How Does the Ideal Gas Law Solve Temperature and Volume Changes in Gases?

The initial pressure is 0.233*10^5 Pa and the final pressure is 0.609*10^5 Pa. The initial temperature is 42 degrees Celsius and the final temperature is what we are trying to find. In summary, the problem involves a cylinder with a movable piston containing gas at a certain temperature, volume, and pressure. The temperature and pressure are changed and the final temperature of the gas is being sought. The ideal gas law is used to solve for the final temperature.
  • #1
mustang
169
0
Problem1. A cylinder with a movable piston contains gas at a temperature of 42 degrees Celicius, with a volume of 40m^3 and a pressure of 0.233*10^5 Pa.
What will be the final temperature of the gas if it is compressed to 0.728 m^3 and its pressure is increaded to 0.609*10^5 Pa? Answer in K.
How is this done?

Problem 3.
A gas bubble with a volume of 0.14 cm^3 is formed at the bottom of a 11.1 cm deep container of merccury. The temperature is 24 degrees Celisius at the bottom of the container and 43 degees Celisuis at the top of the container.
The acceleration of gravity is 9.81 m/s^2.
What is the volume of the bubble just beneath the surface of the mercury? Assume that the surface is at atmospheric pressure.
Answer in units of m^3.
How is correctly done?
 
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  • #2
Well? Where are you stuck? Show what you've done. Start by stating the ideal gas law.
 
  • #3
Problem 3.

For problem what formula would you use?
We only the IDeal Gas Formula :P V = n R T
P is the pressure, V is the volume, n is the number of mols of gas, T is the absolute temperature, and R is the Universal Gas Constant.
If this is a good formula to do this problem can you show your steps, step-by-step.
 
  • #4
Problem 3

Right, you would use the ideal gas law. Since n is a constant (the number of gas atoms doesn't change), I would rewrite it as PV/T = constant. Now compare the values for two points: (1) at the bottom of the mercury column and (2) near the top:
[tex]\frac{P_1V_1}{T_1} = \frac{P_2V_2}{T_2}[/tex]
You have to solve for V2, by plugging in the values for the other variables. You'll have to figure out the pressure at the bottom of that column of mercury, for one! At the top, just assume it's atmospheric pressure.

Give it a shot.
 
  • #5
Doc Al said:
Right, you would use the ideal gas law. Since n is a constant (the number of gas atoms doesn't change), I would rewrite it as PV/T = constant. Now compare the values for two points: (1) at the bottom of the mercury column and (2) near the top:
[tex]\frac{P_1V_1}{T_1} = \frac{P_2V_2}{T_2}[/tex]
You have to solve for V2, by plugging in the values for the other variables. You'll have to figure out the pressure at the bottom of that column of mercury, for one! At the top, just assume it's atmospheric pressure.

Give it a shot.

What would the values of the pressures be if they give you just the volumes and temperatures?
 
  • #6
pressures are given

mustang said:
What would the values of the pressures be if they give you just the volumes and temperatures?
I don't understand your question. In this problem you are given all the information needed to figure out the pressures.
 

FAQ: How Does the Ideal Gas Law Solve Temperature and Volume Changes in Gases?

1. What is the Ideal Gas Law?

The Ideal Gas Law is a mathematical equation that relates the pressure, volume, temperature, and number of moles of an ideal gas. It is represented by the equation PV = nRT, where P is pressure, V is volume, n is the number of moles, R is the ideal gas constant, and T is temperature.

2. What is an ideal gas?

An ideal gas is a theoretical gas that follows the Ideal Gas Law at all temperatures and pressures. It is composed of particles that have no volume and do not interact with each other. Real gases may behave like ideal gases under certain conditions, but they deviate from ideal behavior at high pressures and low temperatures.

3. How do you solve Ideal Gas Law problems?

To solve Ideal Gas Law problems, you need to know three of the four variables (pressure, volume, temperature, and number of moles) and use the Ideal Gas Law equation to find the missing variable. You may also need to convert units to ensure they are consistent. It is important to note that the Ideal Gas Law assumes ideal gas behavior, so it may not always accurately predict the behavior of real gases.

4. What is the ideal gas constant?

The ideal gas constant (R) is a proportionality constant used in the Ideal Gas Law. Its value depends on the units used for pressure, volume, and temperature. The most commonly used value is 0.0821 L·atm/mol·K, but it can also be expressed in units such as J/mol·K or cm^3·atm/mol·K.

5. What are some applications of the Ideal Gas Law?

The Ideal Gas Law is used in many fields, including chemistry, physics, and engineering. It is used to predict the behavior of gases in various conditions, such as in chemical reactions and industrial processes. It is also used to design and analyze gas storage containers, such as scuba tanks and gas cylinders.

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