Normalization constant: Difference between revisions

Using Brillouin-Wigner perturbation theory we will proof that ${\displaystyle Z=\langle N|N\rangle ^{-1}={\frac {\partial E_{n}}{\partial \epsilon _{n}}}}$

In this theory, the exact state and exact energy can be written as follows:

${\displaystyle |N\rangle =|n\rangle +\sum _{k=1}^{+\infty }\lambda ^{k}\left(\sum _{m_{1}}'...\sum _{m_{k}}'|m_{1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{1}}}}\langle m_{1}|H'|m_{2}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{2}}}}\langle m_{2}|H'|m_{3}\rangle ...{\frac {1}{E_{n}-\epsilon _{m_{k-1}}}}\langle m_{k-1}|H'|m_{k}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{k}}}}\langle m_{k}|H'|n\rangle \right)\;({\mathbf {1}})}$

${\displaystyle E_{n}=\epsilon _{n}+\lambda \langle n|H'|n\rangle +}$

${\displaystyle +\sum _{k=1}^{+\infty }\lambda ^{k+1}\left(\sum _{m_{1}}'...\sum _{m_{k}}'\langle n|H'|m_{1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{1}}}}\langle m_{1}|H'|m_{2}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{2}}}}\langle m_{2}|H'|m_{3}\rangle ...{\frac {1}{E_{n}-\epsilon _{m_{k-1}}}}\langle m_{k-1}|H'|m_{k}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{k}}}}\langle m_{k}|H'|n\rangle \right)}$

where ${\displaystyle \sum '}$does not allow the running indexes equal to n.

Taking the derivative of ${\displaystyle E_{n}}$ with respect ${\displaystyle {\mathbf {\epsilon }}_{n}}$ to, using the chain rule ,we get:

${\displaystyle {\frac {\partial E_{n}}{\partial \epsilon _{n}}}=1+0+}$

${\displaystyle +{\frac {\partial E_{n}}{\partial \epsilon _{n}}}\sum _{k=1}^{+\infty }\lambda ^{k+1}{\frac {\partial }{\partial E_{n}}}\left(\sum _{m_{1}}'...\sum _{m_{k}}'\langle n|H'|m_{1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{1}}}}\langle m_{1}|H'|m_{2}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{2}}}}\langle m_{2}|H'|m_{3}\rangle ...{\frac {1}{E_{n}-\epsilon _{m_{k-1}}}}\langle m_{k-1}|H'|m_{k}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{k}}}}\langle m_{k}|H'|n\rangle \right)}$

${\displaystyle =1-{\frac {\partial E_{n}}{\partial \epsilon _{n}}}\sum _{k=1}^{+\infty }\lambda ^{k+1}\sum _{m_{1}}'...\sum _{m_{k}}'\langle n|H'|m_{1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{1}}}}\langle m_{1}|H'|m_{2}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{2}}}}\langle m_{2}|H'|m_{3}\rangle ...}$

${\displaystyle ...{\frac {1}{E_{n}-\epsilon _{m_{p-1}}}}\langle m_{p-1}|H'|m_{p}\rangle .{\frac {1}{(E_{n}-\epsilon _{m_{p}})^{2}}}\langle m_{p}|H'|m_{p+1}\rangle ...{\frac {1}{E_{n}-\epsilon _{m_{k-1}}}}\langle m_{k-1}|H'|m_{k}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{k}}}}\langle m_{k}|H'|n\rangle }$

From this we can solve for ${\displaystyle {\frac {\partial E_{n}}{\partial \epsilon _{n}}}}$

${\displaystyle ({\frac {\partial E_{n}}{\partial \epsilon _{n}}})^{-1}=\sum _{k=1}^{+\infty }\lambda ^{k+1}\sum _{m_{1}}'...\sum _{m_{k}}'\langle n|H'|m_{1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{1}}}}\langle m_{1}|H'|m_{2}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{2}}}}\langle m_{2}|H'|m_{3}\rangle ...}$

${\displaystyle ...{\frac {1}{E_{n}-\epsilon _{m_{p-1}}}}\langle m_{p-1}|H'|m_{p}\rangle .{\frac {1}{(E_{n}-\epsilon _{m_{p}})^{2}}}\langle m_{p}|H'|m_{p+1}\rangle ...{\frac {1}{E_{n}-\epsilon _{m_{k-1}}}}\langle m_{k-1}|H'|m_{k}\rangle .{\frac {1}{E_{n}-\epsilon _{m_{k}}}}\langle m_{k}|H'|n\rangle \qquad \qquad \qquad \qquad ({\mathbf {2}})}$

Now let's evaluate ${\displaystyle Z=\langle N|N\rangle ^{-1}}$ from ${\displaystyle ({\mathbf {1}})}$

${\displaystyle Z^{-1}=1+\left(\sum _{p=1}^{+\infty }\lambda ^{p}\sum _{m_{1}}'...\sum _{m_{p}}'\langle n|H'|m_{p}\rangle {\frac {1}{E_{n}-\epsilon _{m_{p}}}}\langle m_{p}|H'|m_{p-1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{p-1}}}}...\langle m_{2}|H'|m_{1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{1}}}}\langle m_{1}|\right){\mathbf {.}}}$

${\displaystyle {\mathbf {.}}\left(\sum _{q=1}^{+\infty }\lambda ^{q}\sum _{m'_{1}}'...\sum _{m'_{q}}'|m'_{1}\rangle {\frac {1}{E_{n}-\epsilon _{m'_{1}}}}\langle m'_{1}|H'|m'_{2}\rangle ...{\frac {1}{E_{n}-\epsilon _{m'_{q-1}}}}\langle m'_{q-1}|H'|m'_{q}\rangle {\frac {1}{E_{n}-\epsilon _{m'_{q}}}}\langle m'_{q}|H'|n\rangle \right)=}$

${\displaystyle =1+\sum _{p=1}^{+\infty }\sum _{q=1}^{+\infty }\lambda ^{p+q}\sum _{m_{1}}'...\sum _{m_{p}}'\sum _{m'_{1}}'...\sum _{m'_{q}}'\langle n|H'|m_{p}\rangle {\frac {1}{E_{n}-\epsilon _{m_{p}}}}\langle m_{p}|H'|m_{p-1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{p-1}}}}...\langle m_{2}|H'|m_{1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{1}}}}\langle m_{1}|m'_{1}\rangle {\mathbf {.}}}$

${\displaystyle {\mathbf {.}}{\frac {1}{E_{n}-\epsilon _{m'_{1}}}}\langle m'_{1}|H'|m'_{2}\rangle ...{\frac {1}{E_{n}-\epsilon _{m'_{q-1}}}}\langle m'_{q-1}|H'|m'_{q}\rangle {\frac {1}{E_{n}-\epsilon _{m'_{q}}}}\langle m'_{q}|H'|n\rangle }$

We have ${\displaystyle \langle m_{1}|m'_{1}\rangle =\delta _{m_{1}m'_{1}}}$, therefore the summing over ${\displaystyle m'_{1}}$ is equivalent to setting ${\displaystyle m'_{1}=m_{1}}$. We get:

${\displaystyle Z^{-1}=1+\sum _{p=1}^{+\infty }\sum _{q=1}^{+\infty }\lambda ^{p+q}\sum _{m_{1}}'...\sum _{m_{p}}'\sum _{m'_{2}}'...\sum _{m'_{q}}'\langle n|H'|m_{p}\rangle {\frac {1}{E_{n}-\epsilon _{m_{p}}}}\langle m_{p}|H'|m_{p-1}\rangle {\frac {1}{E_{n}-\epsilon _{m_{p-1}}}}...\langle m_{2}|H'|m_{1}\rangle {\frac {1}{(E_{n}-\epsilon _{m_{1}})^{2}}}{\mathbf {.}}}$

${\displaystyle {\mathbf {.}}\langle m_{1}|H'|m'_{2}\rangle ...{\frac {1}{E_{n}-\epsilon _{m'_{q-1}}}}\langle m'_{q-1}|H'|m'_{q}\rangle {\frac {1}{E_{n}-\epsilon _{m'_{q}}}}\langle m'_{q}|H'|n\rangle }$

Let's define ${\displaystyle k=p+q-1}$ and exchange the indexes as follows:

${\displaystyle m_{p}\rightarrow m_{1};\;m_{p-1}\rightarrow m_{2};\;...;m_{1}\rightarrow m_{p}}$

${\displaystyle m'_{2}\rightarrow m_{p+1};\;m'_{3}\rightarrow m_{p+2};\;...;m'_{q}\rightarrow m_{p+q-1}=m_{k}}$

Doing so we can see that ${\displaystyle Z^{-1}}$ exactly equals to ${\displaystyle ({\frac {\partial E_{n}}{\partial \epsilon _{n}}})^{-1}}$ given in (2). Therefore:

${\displaystyle Z=\langle N|N\rangle ^{-1}={\frac {\partial E_{n}}{\partial \epsilon _{n}}}}$