Ideal gas Helmholtz energy function: Difference between revisions

Revision as of 15:20, 21 February 2007

From equations

Q_{NVT}={\frac {1}{N!}}\left({\frac {V}{\Lambda ^{3}}}\right)^{N}

and

\left.A\right.=-k_{B}T\ln Q_{NVT}

one has

A=-k_{B}T\left(\ln {\frac {1}{N!}}+N\ln {\frac {V}{\Lambda ^{3}}}\right)

=-k_{B}T\left(-\ln N!+N\ln {\frac {VN}{\Lambda ^{3}N}}\right)

=-k_{B}T\left(-\ln N!+N\ln {\frac {N}{\Lambda ^{3}\rho }}\right)

=-k_{B}T\left(-N\ln N+N+N\ln N-N\ln \Lambda ^{3}\rho \right)

one arrives at

$A=Nk_{B}T\left(\ln \Lambda ^{3}\rho -1\right)$

@@ Line 2: / Line 2: @@
 :<math>Q_{NVT}=\frac{1}{N!} \left( \frac{V}{\Lambda^{3}}\right)^N</math>
 and
-:<math>A=-k_B T \ln Q_{NVT}</math>
+:<math>\left.A\right.=-k_B T \ln Q_{NVT}</math>
 one has
 :<math>A=-k_BT\left(\ln \frac{1}{N!} + N\ln\frac{V}{\Lambda^{3}}\right)</math>