Solving a Monatomic Gas Cooling Problem

In summary, the conversation is about a monatomic gas being cooled by 50 C at constant volume by removing 830 J of energy. The main principle in this question is the First Law of Thermodynamics, where dQ = dU + dW and dW = 0 as volume is constant. For monoatomic gases, the molar specific heat at constant volume is 3/2.R and dU = nCdT, where n is the number of moles. The formulas used were not explicitly taught but are in the book.
  • #1
rgo
7
0
I really have no Idea where to start... Please help

Homework Statement


A monatomic gas is cooled by 50 C at constant volume by removing 830 J of energy. How many moles of the gas is in the sample.


Homework Equations



?Q=mc (delta)T



The Attempt at a Solution




I am not sure where to start...a monatomic gas could be any of the noble gases, right? each with a different molecular weight and each would have a different specific heat at a constant volume(c). Is this even the right equation to start with. Thanks.
 
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  • #2
The main principle in this question is the First law of Thermodynamics
By 1st Law, dQ=dW+dU (using d for delta,nevertheless)
dW=0 as volume is constant
So, dQ=dU

Now, for monoatomic gases, Molar specific heat at constant volume is given by 3/2.R,where R=gas const.
as dU=nCdT, the values can be substituted to get the only unknown n, which is the no.of moles.

(Monoatomic is explicitly mentioned so that the Cv of the gas can be found out based on equipartition of energy)
 
  • #3
Thanks

Thank you... That was perfect. It is frustrating because the formulas you used were never taught to me. They are in the book but they are outside the material we were required to learn. But my teacher is like that... Any how thanks for your help.
 

1. How do you calculate the final temperature of a monatomic gas after cooling?

The final temperature of a monatomic gas after cooling can be calculated using the equation T2 = T1 * (V2/V1)^2, where T1 and V1 are the initial temperature and volume, and T2 and V2 are the final temperature and volume.

2. What is the ideal gas law and how is it used to solve cooling problems?

The ideal gas law, PV = nRT, is a formula that describes the relationship between pressure, volume, number of moles, and temperature of an ideal gas. It can be used to solve cooling problems by rearranging the equation to solve for the final temperature, T2 = (P2V2)/(nR), where P2 is the final pressure and n is the number of moles.

3. How does the specific heat capacity affect the cooling of a monatomic gas?

The specific heat capacity of a monatomic gas, which is the amount of heat required to raise the temperature of one mole of the gas by one degree, determines how much energy is needed to cool the gas. A higher specific heat capacity means more energy is required to cool the gas, resulting in a slower rate of cooling.

4. Can the rate of cooling for a monatomic gas be affected by its initial temperature?

Yes, the initial temperature of a monatomic gas can affect its rate of cooling. A gas with a higher initial temperature will have more thermal energy, and therefore will cool at a faster rate than a gas with a lower initial temperature.

5. How does the volume of a container affect the cooling of a monatomic gas?

The volume of a container can affect the cooling of a monatomic gas by changing the pressure and temperature of the gas. When a gas is cooled, its volume decreases, resulting in an increase in pressure. This change in pressure can also affect the rate of cooling of the gas. Additionally, a smaller container will have a smaller surface area, which can affect the rate of heat transfer and therefore the cooling rate of the gas.

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