Jost function

In scattering theory, the Jost function is the Wronskian of the regular solution and the (irregular) Jost solution to the differential equation ${\displaystyle -{\psi }^{″}+V\psi =k^2\psi }$. It was introduced by Res Jost.

We are looking for solutions ${\displaystyle \psi (k,r)}$ to the radial Schrödinger equation in the case ${\displaystyle \ell =0}$,

${\displaystyle -{\psi }^{″}+V\psi =k^2\psi .}$

A regular solution ${\displaystyle \phi (k,r)}$ is one that satisfies the boundary conditions,

${\displaystyle \begin{array}{cc}\phi (k,0)& =0\\ {{\phi }_r}^{\prime }(k,0)& =1.\end{array}}$

If ${\displaystyle {\displaystyle \underset{0}{\overset{\mathrm{\infty }}{\int }}}r|V(r)|<\mathrm{\infty }}$, the solution is given as a Volterra integral equation,

${\displaystyle \phi (k,r)=k^{-1}\sin (kr)+k^{-1}{\displaystyle \underset{0}{\overset{r}{\int }}}d{r}^{\prime }\sin (k(r-r^{\prime }))V(r^{\prime })\phi (k,r^{\prime }).}$

There are two irregular solutions (sometimes called Jost solutions) ${\displaystyle f_{\pm }}$ with asymptotic behavior ${\displaystyle f_{\pm }=e^{\pm ikr}+o(1)}$ as ${\displaystyle r\to \mathrm{\infty }}$. They are given by the Volterra integral equation,

${\displaystyle f_{\pm }(k,r)=e^{\pm ikr}-k^{-1}{\displaystyle \underset{r}{\overset{\mathrm{\infty }}{\int }}}d{r}^{\prime }\sin (k(r-r^{\prime }))V(r^{\prime })f_{\pm }(k,r^{\prime }).}$

If ${\displaystyle k\ne 0}$, then ${\displaystyle f_{+},f_{-}}$ are linearly independent. Since they are solutions to a second order differential equation, every solution (in particular ${\displaystyle \phi }$) can be written as a linear combination of them.

The Jost function is

${\displaystyle \omega (k):=W(f_{+},\phi )\equiv {{\phi }_r}^{\prime }(k,r)f_{+}(k,r)-\phi (k,r)f_{{+}^{\prime },r}(k,r)}$,

where W is the Wronskian. Since ${\displaystyle f_{+},\phi }$ are both solutions to the same differential equation, the Wronskian is independent of r. So evaluating at ${\displaystyle r=0}$ and using the boundary conditions on ${\displaystyle \phi }$ yields ${\displaystyle \omega (k)=f_{+}(k,0)}$.

The Jost function can be used to construct Green's functions for

${\displaystyle [-\frac{{\partial }^2}{\partial r^2}+V(r)-k^2]G=-\delta (r-r^{\prime }).}$

In fact,

${\displaystyle G^{+}(k;r,r^{\prime })=-\frac{\phi (k,r\wedge r^{\prime })f_{+}(k,r\vee r^{\prime })}{\omega (k)},}$

where ${\displaystyle r\wedge r^{\prime }\equiv \min (r,r^{\prime })}$ and ${\displaystyle r\vee r^{\prime }\equiv \max (r,r^{\prime })}$.

The analyticity of the Jost function in the particle momentum ${\displaystyle k}$ allows to establish a relationship between the scatterung phase difference with infinite and zero momenta on one hand and the number of bound states ${\displaystyle n_b}$, the number of Jaffe - Low primitives ${\displaystyle n_p}$, and the number of Castillejo - Daliz - Dyson poles ${\displaystyle n_{\text{CDD}}}$ on the other (Levinson's theorem):

${\displaystyle \delta (+\mathrm{\infty })-\delta (0)=-\pi (\frac{1}{2}{n}_0+n_b+n_p-n_{\text{CDD}})}$.

Here ${\displaystyle \delta (k)}$ is the scattering phase and ${\displaystyle n_0}$ = 0 or 1. The value ${\displaystyle n_0=1}$ corresponds to the exceptional case of a ${\displaystyle s}$-wave scattering in the presence of a bound state with zero energy.

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