176 - Pr 16 - Graham Law of Effusion for Two Boltzmann Gases

Consider two Boltzmann gases A and B, at pressures P A and P B and temperatures T  A and T  B , respectively, contained in two regions of space that communicate through a very narrow opening in the partitioning wall,

[I.1] Show that the dynamic equilibrium resulting from the mutual effusion of the two kinds of molecules, rather than ???

P A

=

1

PB  , satisfies the condition,

That the two effusion rates are equal means, given that a Boltzmann gas is an ideal gas for which we have equipartition of energy,  R A

=

RB

→

1 4

=

nA u A

1 4

n B uB

→

nA

kT A m A

=

nB

kTB

n =N / V ∝ P /T ;   2 1 mv = 12 kT   2

→

mB

PA

k TA

TA

mA

=

PB

kTB

TB

mB

→

PA

=

PB

TA m A TBm B

[I.2]

Appendix: derivation of the effusion rate from Pathria

[I.3] Consider velocities over the range [u, u + d u ] . Normalization condition,

∫

all velocities

[I.4]

 f ( u ) ⋅ d u ≡ 1

How many particles will strike dA in time dt? Vinc = dA • u ⋅ dt → dninc = Vinc × d ρ = ( dA • u ⋅ dt ) ⋅ (n ⋅ f ( u) ⋅ du ) ;

d ρ ∆p z

= ∆p z ⋅ u zd ρ  =

p zu z

=n

  2 p zu z (nf ( u) ⋅ d u ) [I.5]

Integrating the density [I.5] over a volume gives pressure,

∫

P = n ⋅ d ρ ∆ p z

=

∫ 2np u z

z

∫

f ( u) ⋅ d 3u = n ( p zu z ) ⋅ f ( u) ⋅ d 3u

=n

pu cos 2 θ 

=

1 3

n pu

[I.6]

Effusion

We are integrating from θ  = [0, π 2 ] , half the range you might expect, since we are considering only u z is, only the particles that make it through the hole. Using the normalization  R

=

∫

3

n u z f (u )d u

∞

=

n

∫ ∫ 0

2π

0

×

∫

π /2

0

2

u cos θ f (u ) ⋅ u sin θ ⋅ du ⋅ d θ ⋅ d φ

For more info: see SMT 01, p. 14, pr 22.

1

Which would be the case if the equilibrium had resulted from a h ydrodynamic flow

∫

∞

0

=

 f (u) d 3u =

nπ

∫

∞

0

∫

∞

0

3

>

0 --that

f ( u)4π u 2du ≡ 1 ,

  f (u )u du =

1 4

n⋅ u

[I.7]