1549380323-Statistical Mechanics Theory and Molecular Simulation

Particle number fluctuations 277

From eqn. (6.6.9), it follows that

∂P

∂μ

=

∂P

∂v

∂v

∂μ

=−

∂^2 a

∂v^2

∂v

∂μ

. (6.6.10)

We can obtain an expression for∂μ/∂vby

μ=

∂A

∂N

=a(v,T) +N

∂a

∂v

∂v

∂N

=a(v,T)−v

∂a

∂v

, (6.6.11)

so that

∂μ

∂v

=

∂a

∂v

−

∂a

∂v

−v

∂^2 a

∂v^2

=−v

∂^2 a

∂v^2

. (6.6.12)

Substituting this result into eqn. (6.6.10) gives

∂P

∂μ

=−

∂^2 a

∂v^2

[

∂μ

∂v

]− 1

=

∂^2 a

∂v^2

[

v

∂^2 a

∂v^2

]− 1

=

1

v

. (6.6.13)

Differentiating eqn. (6.6.13) once again with respect toμgives

∂^2 P

∂μ^2

=−

1

v^2

∂v

∂μ

=

1

v^2

[

v

∂^2 a

∂v^2

]− 1

=−

1

v^3 ∂P/∂v

. (6.6.14)

Now, recall that the isothermal compressibility is given by

κT=−

1

V

∂V

∂P

=−

1

v

∂v

∂P

=−

1

v∂P/∂v

(6.6.15)

and is an intensive quantity. It is clear from eqn. (6.6.14) that∂^2 P/∂μ^2 can be ex-
pressed in terms ofκTas
∂^2 P
∂μ^2

=

1

v^2

κT, (6.6.16)

so that

(∆N)^2 =kT〈N〉v

1

v^2

κT=

〈N〉kTκT

v

, (6.6.17)

where the specific value ofNhas been replaced by its average value〈N〉in the grand
canonical ensemble. The relative fluctuations in particle number cannow be computed
from