Heating gas at constant volume/pressure

AI Thread Summary
To calculate the energy required to heat 0.33 mol of oxygen gas from 300K to 500K at constant pressure, the specific heat capacity at constant pressure (C_p) is used, yielding the formula Q = C_p ν ΔT. For oxygen, with 5 degrees of freedom, C_p is determined to be (7/2)R. In contrast, for 0.33 mol of argon, which is monatomic, the energy required at constant volume is calculated using C_v, resulting in Q = C_v ν ΔT, where C_v is (3/2)R. The calculations for both gases are confirmed to be correct, demonstrating the application of the First Law of Thermodynamics.
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Homework Statement


A vessel containing 0.33 mol of oxygen gas is allowed to expand at constant pressure while being heated. How much energy is required to raise the temperature of the gas from 300K to 500K?

If the same vessel contains 0.33 mol of argon, calculate the energy required to raise the temperature from 300K to 500K, whilst maintaing the gas at constant volume.

Homework Equations


##\Delta E = Q + W##, (First Law of Thermodynamics)

The Attempt at a Solution


At 300K, oxygen exhibits 5 degrees of freedom, so ##C_v = \frac{5}{2}R \Rightarrow C_p = \frac{7}{2}R## At constant pressure, when the gas is being heated up, it must do work and expand (otherwise if it didn't, it's internal energy would increase and thus the pressure on the container). So then ##Q = C_p \nu \Delta T ##, with ##\nu = 0.33, \Delta T = 200##.

Argon is monatomic so ##C_v = \frac{3}{2}R.## At constant volume, the gas does no work so all the heat energy goes into increasing the total internal energy of the gas. This is ##Q = C_v \nu \Delta T ## with the same numbers used above.

Is it correct?

Many thanks.
 
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