Answer:
a. [tex]D_{A-B}=0.0838\frac{cm^2}{s}[/tex]
b. [tex]D_{A-B} =0.460\frac{cm^2}{s}[/tex]
Explanation:
Hello!
In this case, since the Hirschfelder's equation is:
[tex]D_{A-B}=0.0018583\sqrt{T^3(\frac{1}{M_A} +\frac{1}{M_B} )}\frac{1}{p\sigma ^2_{A-B}\Omega _{D,A-B}}[/tex]
Whereas M is the molar mass and sigma is related to the size of the molecule and omega the collision integral depending on the dimensionless temperature and are parameters related to the Chapman-Enskog theory and the Lenard-Jones parameters which have been tabulated for sulfur dioxide, nitrogen, hydrogen and air. Thus, we proceed as follows:
a. In this case, we have that sigma for sulfur dioxide is 4.026 and that of nitrogen is 3.667, and the parameter e/K is 363 K and 99.8 K respectively.
It means that the pairs are:
[tex]\sigma _{A-B}=\frac{1}{2} (4.026+3.667)=3.8465[/tex]
[tex]e_{A-B}/K=\sqrt{363*99.8}=190.33[/tex]
For which:
[tex]\Omega _{D,A-B}=1.180[/tex]
Based on Bird's E2 table.
Now, by plugging in the data, we obtain the following diffusion coefficient:
[tex]D_{A-B}=0.0018583\sqrt{(298K)^3(\frac{1}{64} +\frac{1}{28} )}\frac{1}{1.48atm*3.8465^2*1.180}=0.0838\frac{cm^2}{s}[/tex]
b. In this case, we have that sigma for hydrogen is 2.915 and that of air is 3.617, and the parameter e/K is 30.8 K and 97.0 K respectively.
It means that the pairs are:
[tex]\sigma _{A-B}=\frac{1}{2} (2.915+3.617)=3.266[/tex]
[tex]e_{A-B}/K=\sqrt{30.8*97.0}=54.66[/tex]
For which:
[tex]\Omega _{D,A-B} =0.8202[/tex]
Based on Bird's E2 table.
Now, by plugging in the data, we obtain the following diffusion coefficient:
[tex]D_{A-B}=0.0018583\sqrt{(325K)^3(\frac{1}{2.02} +\frac{1}{28.96} )}\frac{1}{1.97atm*3.266^2*0.8202}=0.460\frac{cm^2}{s}[/tex]
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