Answer:
PNO₂ = 0.49 atm
PN₂O₄ = 0.45 atm
Explanation:
Let's begin with the equation of ideal gas, and derivate from it an equation that involves the density (ρ = m/V).
PV = nRT
n = m/M (m is the mass, and M the molar mass)
[tex]PV = \frac{m}{M}RT[/tex]
[tex]PxM = \frac{m}{V}RT[/tex]
PxM = ρRT
ρ = PxM/RT
With the density of the gas mixture, we can calculate the average of molar mass (Mavg), with the constant of the gases R = 0.082 atm.L/mol.K, and T = 16 + 273 = 289 K
[tex]2.7 = \frac{0.94xMavg}{0.082x289}[/tex]
0.94Mavg = 63.9846
Mavg = 68.0687 g/mol
The molar mass of N is 14 g/mol and of O is 16 g/mol, than [tex]M_{NO2} = 46[/tex] g/mol and [tex]M_{N2O4} = 96[/tex] g/mol. Calling y the molar fraction:
[tex]Mavg = M_{NO2}y_{NO2} + M_{N2O4}y_{N2O4}[/tex]
And,
[tex]y_{NO2} + y_{N2O4} = 1[/tex]
[tex]y_{N2O4} = 1 - y_{NO2}[/tex]
So,
[tex]68.0687 = 46y_{NO2} + 92x(1 - y_{NO2})[/tex]
[tex]68.0687 - 92 = 46y_{NO2} - 92y_{NO2}[/tex]
[tex]46y_{NO2} = 23.9313[/tex]
[tex]y_{NO2} = 0.52[/tex]
[tex]y_{N2O4} = 0.48[/tex]
The partial pressure is the molar fraction multiplied by the total pressure so:
PNO₂ = 0.52x0.94 = 0.49 atm
PN₂O₄ = 0.48x0.94 = 0.45 atm
