Answer:
7.71 atm
Explanation:
Given the following data:
[tex]V = 5 L[/tex]
[tex]n_{He} = 3 mol[/tex]
[tex]n_{H_2} = 4 mol[/tex]
[tex]p_1 = 9 atm[/tex]
[tex]T = const[/tex]
According to the ideal gas law, we know that the product between pressure and volume of a gas is equal to the product between moles, the ideal gas law constant and the absolute temperature:
[tex]pV = nRT[/tex]
Since the temperature and the ideal gas constant are constants, as well as the fixed container volume of 5 L, we may rearrange the equation as:
[tex]\frac{p}{n}=\frac{RT}{V}=const[/tex]
This means for two conditions, we'd obtain:
[tex]\frac{p_1}{n_1}=\frac{p_2}{n_2}[/tex]
Given:
[tex]p_1 = 9 atm[/tex]
[tex]n_1 = n_{initial total} = n_{He} + n_{H_2} = 3 mol + 4 mol = 7 mol[/tex]
[tex]n_2 = n_{final total} = n_{He} + n_{H_2} = 3 mol + 4 mol + 2 mol = 9 mol[/tex]
Solve for the final pressure:
[tex]p_2 = p_1\cdot \frac{n_2}{n_1}[/tex]
Now, according to the Dalton's law of partial pressures, the partial pressure is equal to the total pressure multiplied by the mole fraction of a component:
[tex]p_{H_2}=\chi_{H_2}p_2[/tex]
Knowing that:
[tex]p_2 = p_1\cdot \frac{n_2}{n_1}[/tex]
And:
[tex]\chi_{H_2}=\frac{n_H_2}{n_2}[/tex]
The equation becomes:
[tex]p_{H_2}=\chi_{H_2}p_2=p_1\cdot \frac{n_2}{n_1}\cdot \frac{n_H_2}{n_2}=p_1\cdot \frac{n_H_2}{n_1}[/tex]
Substituting the variables:
[tex]p_{H_2}=9 atm\cdot \frac{4 mol + 2 mol}{7 mol}=7.71 atm[/tex]
