- Scattering length
The scattering length in
quantum mechanics describes low-energyscattering . It is represented by the term a.General concept
When a slow particle scatters off a short ranged scatterer (e.g. an impurity in a solid or a heavy particle) it cannot resolve the structure of the object since its de Broglie wavelength is very long. The idea is that then it should not be important what precise potential V(r) one scatters off, but only how the potential looks at long length scales. The formal way to solve this problem is to do a partial wave expansion (somewhat analogous to the
multipole expansion in classical electrodynamics), where one expands in theangular momentum components of the outgoing wave. At very low energy the incoming particle does not see any structure, therefore to lowest order one has only a spherical symmetric outgoing wave, the so called s-wave scattering (angular momentum l=0). At higher energies one also needs to consider p and d-wave (l=1,2) scattering and so on. The concept behind describing low energy properties in terms of a few parameters and symmetries is the idea ofrenormalization .Example
As an example on how to compute the s-wave (i.e. angular momentum l=0) scattering length for a given potential we look at the infinitely repulsive spherical
potential well of radius r_0 in 3 dimensions. The radial Schrödinger equation (l=0) outside of the well is just the same as for a free particle::frac{hbar^2}{2m} u"(r)=E u(r),
where the hard core potential requires that the
wave function u(r) vanishes at r=r_0, u(r_0)=0.The solution is readily found::u(r)=A sin(k r+delta_s).
Here k=sqrt{2m E}/hbar; delta_s=-k cdot r_0 is the s-wave
phase shift (the phase difference between incoming and outgoing wave), which is fixed by the boundary condition u(r_0)=0; A is an arbitrary normalization constant.One can show that in general delta_s(k)approx-k cdot a_s +O(k^2) for small k (i.e. low energy scattering). The parameter a_s of dimension length is defined as the scattering length. For our potential we have therefore a=r_0, in other words the scattering length for a hard sphere is just the radius. (Alternatively one could say that an arbitrary potential with s-wave scattering length a_s has the same low energy scattering properties as a hard sphere of radius a_s).To relate the scattering length to physical observables that can be measured in a scattering experiment we need to compute the
cross section sigma. Inscattering theory one writes the asymptotic wavefunction as (we assume there is a finite ranged scatterer at the origin and there is an incoming plane wave along the z-axis):psi(r, heta)=e^{i k z}+f( heta) frac{e^{i k r{r}
where f is the
scattering amplitude . According to the probability interpretation of quantum mechanics thedifferential cross section is given by dsigma/dOmega=|f( heta)|^2 (the probability per unit time to scatter into the direction mathbf{k}). If we consider only s-wave scattering the differential cross section does not depend on the angle heta, and the totalscattering cross section is just sigma=4 pi |f|^2. The s-wave part of the wavefunction psi(r, heta) is projected out by using the standard expansion of a plane wave in terms of spherical waves andLegendre polynomials P_l(cos heta):e^{i k z}approxfrac{1}{2 i k r}sum_{l=0}^{infty}(2l+1)P_l(cos heta)left [ (-1)^{l+1}e^{-i k r} + e^{i k r} ight]
By matching the l=0 component of psi(r, heta) to the s-wave solution psi(r)=A sin(k r+delta_s)/r (where we normalize A such that the incoming wave e^{i k z} has a prefactor of unity) one has
:f=frac{1}{2 i k}(e^{2 i delta_s}-1)approx delta_s/k approx - a_s
This gives
sigma= frac{4 pi}{k^2} sin^2 delta_s =4 pi a_s^2
References
*
L. D. Landau ,E. M. Lifshitz Quantum Mechanics: Non-relativistic Theory ISBN 0 7506 3539 8
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