A.13 In­te­gral Schrö­din­ger equa­tion

The Hamil­ton­ian eigen­value prob­lem, or time-in­de­pen­dent Schrö­din­ger equa­tion, is the cen­tral equa­tion of quan­tum me­chan­ics. It reads

\begin{displaymath}
\frac{\hbar^2}{2m} \nabla^2 \psi({\skew0\vec r}) + V({\skew0\vec r}) \psi({\skew0\vec r}) = E \psi({\skew0\vec r})
\end{displaymath}

Here $\psi$ is the wave func­tion, $E$ is the en­ergy of the state de­scribed by the wave func­tion, $V$ is the po­ten­tial en­ergy, $m$ is the mass of the par­ti­cle, and $\hbar$ is the scaled Planck con­stant.

The equa­tion also in­volves the Lapla­cian op­er­a­tor, de­fined as

\begin{displaymath}
\nabla^2 \equiv \frac{\partial^2}{\partial x^2}+
\frac{\partial^2}{\partial y^2}+ \frac{\partial^2}{\partial z^2}
\end{displaymath}

There­fore the Hamil­ton­ian eigen­value prob­lem in­volves par­tial de­riv­a­tives, and it is called a par­tial dif­fer­en­tial equa­tion.

How­ever, it is pos­si­ble to ma­nip­u­late the equa­tion so that the wave func­tion $\psi$ ap­pears in­side an in­te­gral rather than in­side par­tial de­riv­a­tives. The equa­tion that you get this way is called the in­te­gral Schrö­din­ger equa­tion. It takes the form, {D.31}:

\begin{displaymath}
\fbox{$\displaystyle
\psi({\skew0\vec r}) = \psi_0({\skew0...
...0\vec r}^{ \prime}
\qquad k = \frac{\sqrt{2mE}}{\hbar}
$} %
\end{displaymath} (A.42)

Here $\psi_0$ is any wave func­tion of en­ergy $E$ in free space. In other words $\psi_0$ is any wave func­tion for the par­ti­cle in the ab­sence of the po­ten­tial $V$. The con­stant $k$ is a mea­sure of the en­ergy of the par­ti­cle. It also cor­re­sponds to a wave num­ber far from the po­ten­tial. While not strictly re­quired, the in­te­gral Schrö­din­ger equa­tion above tends to be most suited for par­ti­cles in in­fi­nite space.