Stirling's approximation

James Stirling (1692-1770, Scotland)

${\displaystyle \left.\ln N!\right.=\ln 1+\ln 2+\ln 3+...+\ln N=\sum _{k=1}^{N}\ln k.}$

Because of Euler-MacLaurin formula

${\displaystyle \sum _{k=1}^{N}\ln k=\int _{1}^{N}\ln x\,dx+\sum _{k=1}^{p}{\frac {B_{2k}}{2k(2k-1)}}\left({\frac {1}{n^{2k-1}}}-1\right)+R,}$

where B₁ = −1/2, B₂ = 1/6, B₃ = 0, B₄ = −1/30, B₅ = 0, B₆ = 1/42, B₇ = 0, B₈ = −1/30, ... are the Bernoulli numbers, and R is an error term which is normally small for suitable values of p.

Then, for large N,

${\displaystyle \ln N!\sim \int _{1}^{N}\ln x\,dx\sim N\ln N-N.}$

after some further manipulation one arrives at

${\displaystyle N!={\sqrt {2\pi N}}\;N^{N}e^{-N}e^{\lambda _{N}}}$

where

${\displaystyle {\frac {1}{12N+1}}<\lambda _{N}<{\frac {1}{12N}}.}$

For example:

As one usually deals with number of the order of the Avogadro constant (${\displaystyle 10^{23}}$) this formula is essentially exact. In computer simulations the number of atoms or molecules (N) is invariably greater than 100, where the percentage error is less than .

Applications in statistical mechanics

• Ideal gas Helmholtz energy function