4.3 Solutions 259
of mass these two collisions appear to be equivalent so thatc′=c. We can
then write
f(ν 1 )f(ν 2 )=f(ν 3 )f(ν 4 )
or lnf(ν 1 )+lnf(ν 2 )=lnf(ν 3 )+lnf(ν 4 )(1)
Since kinetic energy is conserved
ν 12 +ν^22 =ν 32 +ν^24 (2)
Equations (1) and (2) are satisfied if
lnf(ν)∝ν^2 (3)
orf(ν)=Aexp(−αν^2 )(4)
whereAandαare constants. The negative sign is essential to ensure that no
molecule can have infinite energy.
LetN(ν)dνbe the number of molecules per unit volume with speedsνto
+dν, irrespective of direction. As the velocity distribution is assumed to be
spherically symmetrical,N(ν)dνis equal to the number of velocity vectors
whose tips end up in the volume of the shell defined by the radiiνand+dν,
so thatN(ν)dν= 4 πν^2 f(ν)dν (5)
Using (4) in (5)N(ν)dν= 4 πAν^2 exp(−αν^2 )(6)We can now determineAandα.IfNis the total number of molecules per
unit volume,N=
∫∞
0N(ν)dν (7)Using (6) in (7)N= 4 πA∫∞
0ν^2 exp(−αν^2 )dν= 4 πA(1/4)(π/α^3 )^1 /^2orN=A(π/α)^3 /^2 (8)IfEis the total kinetic energy of the molecules per unit volumeE=
1
2
m∫∞
0ν^2 N(ν)dν=4 πAm
2∫∞
0ν^4 exp(−αν^2 )dνorE=(3mA/4)(π^3 /α^5 )^1 /^2 (9)where gamma functions have been used for the evaluation of the two integrals.
Further,