How would you rank the following gases, NO, Ar, N_2, N_2O_5, in order of increasing speed of effusion through a tiny opening and increasing time of effusion?

1 Answer
Truong-Son N.
Oct 16, 2016

Z_("eff",N_2) > Z_("eff",NO) > Z_("eff",Ar) > Z_("eff",N_2O_5)

Clearly, the rate is the reciprocal of the time it takes, since the rate is in "s"^(-1) and the time is in "s". Therefore:

t_("eff",N_2) < t_("eff",NO) < t_("eff",Ar) < t_("eff",N_2O_5)

The rate of effusion, which I will denote as Z_"eff", is defined in Graham's Law of Effusion as:

Z_("eff",1)/(Z_("eff",2)) = sqrt(M_(m,2)/(M_(m,1))

where M_(m,i) is the molar mass of compound i and Z_("eff",i) is the rate of effusion of compound i.

Since Z_("eff",1) prop 1/sqrt(M_(m,1)) the higher the molar mass, the slower the rate of effusion, which makes sense since the larger the gas, the less often it can get through a small hole.

M_(m,NO) = 14.007 + 15.999 = "30.006 g/mol"
M_(m,Ar) = "39.948 g/mol"
M_(m,N_2) = 2xx14.007 = "28.014 g/mol"
M_(m,N_2O_5) = 2xx14.007 + 5xx15.999 = "108.009 g/mol"

So, the ranking of molar masses goes as:

M_(m,N_2) < M_(m,NO) < M_(m,Ar) < M_(m,N_2O_5)

which means that:

color(blue)(Z_("eff",N_2) > Z_("eff",NO) > Z_("eff",Ar) > Z_("eff",N_2O_5))

Related questions
See all questions in Kinetic Theory of Gases
Impact of this question
13011 views around the world
You can reuse this answer
Creative Commons License