Partial wave

Partial waves , literally part waves, a concept of quantum mechanics , are stationary solutions of a scattering problem and simultaneously eigenfunctions of angular momentum . The decomposition of a scattering amplitude into partial waves , i. H. a series expansion according to angular momentum is particularly useful for interactions with a short range, such as B. the strong interaction . Because of the short range, only small angular impulses contribute to the scattering for low energies.

Explanation in the particle picture

If a moving particle is in the field of a scattering center - e.g. B. of an atomic nucleus - deflected from its orbit, an orbital angular momentum belongs to this movement . This can only assume discrete values described by a quantum number ; in individual cases it depends on the impact parameter for a given particle velocity . The contributions of the individual processes are called partial waves in the wave pattern and each have a characteristic effect, e.g. B. in the distribution of the total scattered particles in the scattering directions, the angular distribution . ${\ displaystyle l}$ ${\ displaystyle l = 0,1,2, \ dots}$

The code letters for the values of are used in the same way as for the bound electron in the atom , so one speaks of the s-wave ( ), p-wave ( ), d-wave ( ) etc. ${\ displaystyle l}$ ${\ displaystyle l = 0}$ ${\ displaystyle l = 1}$ ${\ displaystyle l = 2}$

Derivation

The aim is to find a solution to the Schrödinger equation for a spherically symmetrical potential such as B. to find the Coulomb potential . ${\ displaystyle V ({\ vec {r}}) = V (r)}$

The wave function is used for asymptotic distances as the superposition of an incoming plane wave and a spherical wave modified by the scattering amplitude : ${\ displaystyle \ psi _ {\ vec {k}} ({\ vec {r}})}$ ${\ displaystyle r \ rightarrow \ infty}$ ${\ displaystyle f (\ theta, \ phi)}$

{\ displaystyle \ psi _ {\ vec {k}} ({\ vec {r}}) {\ xrightarrow {r \ rightarrow \ infty}} [e ^ {i {\ vec {k}} {\ vec {r }}} + f (\ theta, \ phi) {\ frac {e ^ {ikr}} {r}}]}

In this case the scattering amplitude is independent of the angle due to the spherical symmetry : ${\ displaystyle \ phi}$

{\ displaystyle f (\ theta, \ phi) = f (\ theta)}

After a few transformations, the solution wave function of the scattering problem for asymptotic distances results as:

{\ displaystyle \ psi _ {\ vec {k}} ({\ vec {r}}) = \ sum _ {l = 0} ^ {\ infty} i ^ {l} (2l + 1) \; R_ { lk} (r) \; P_ {l} (\ cos \ theta)}

where are the Legendre polynomials . ${\ displaystyle P_ {l} (\ cos \ theta)}$

${\ displaystyle R_ {lk}}$ is the solution of the radial Schrödinger equation, which consists of a linear combination of the spherical Bessel functions and the Von Neumann function : ${\ displaystyle j_ {l} (\ rho)}$ ${\ displaystyle n_ {l} (\ rho)}$

{\ displaystyle R_ {lk} {\ stackrel {\ mathrm {r \ rightarrow \ infty}} {=}} A_ {l} \; j_ {l} (kr) + B_ {l} \; n_ {l} ( kr)}

In the next step, the scattering phase is defined as follows: ${\ displaystyle \ delta _ {l}}$

{\ displaystyle A_ {l} = + a_ {l} \ cos \ delta _ {l}}

{\ displaystyle B_ {l} = - a_ {l} \ sin \ delta _ {l}}

The phase of the outgoing spherical wave is shifted by the potential : with elastic scattering , the scattered wave differs from the undisturbed wave of the free particle only by a phase factor ${\ displaystyle V (r)}$ ${\ displaystyle e ^ {i \ cdot \ delta _ {l}}.}$

By inserting the spherical Bessel and Von-Neumann functions and comparing them with the approach for the wave function for asymptotic distances, after a few transformations one comes to the following relationship between the scattering amplitude and the scattering phase : ${\ displaystyle f (\ theta)}$ ${\ displaystyle \ delta _ {l}}$

{\ displaystyle f (\ theta) = \ sum _ {l = 0} ^ {\ infty} (2l + 1) \; f_ {l} (\ delta _ {l}) \; P_ {l} (\ cos \ theta)}

in which

{\ displaystyle f_ {l} (\ delta _ {l}) = {\ frac {1} {k}} e ^ {i \ cdot \ delta _ {l}} \ sin \ delta _ {l}}

represents the contribution of the l th partial wave.

Spread length

Another important parameter for the analysis of scattering problems, which can be derived from the scattering amplitude, is the scattering length a . It results from the total scattering cross-section when the energy of the scattered particle approaches 0:

{\ displaystyle {\ begin {aligned} \ lim _ {k \ to 0} \ sigma _ {\ text {total}} & = 4 \ pi \ cdot a ^ {2} \\\ Leftrightarrow a & = \ pm {\ sqrt {\ frac {\ lim _ {k \ to 0} \ sigma _ {\ text {total}}} {4 \ pi}}} \ end {aligned}}}

The scattering length therefore corresponds to an effective cross-sectional area, which shows both the strength and the type of a potential.

With the following definition for the total cross section:

{\ displaystyle \ sigma _ {\ text {total}} = \ int _ {4 \ pi} {\ frac {d \ sigma} {d \ Omega}} \ cdot d \ Omega = \ int _ {4 \ pi} | f (\ theta) | ^ {2} \ cdot d \ Omega = {\ frac {4 \ pi} {k ^ {2}}} \ sum _ {l = 0} ^ {\ infty} (2l + 1 ) \ sin ^ {2} \ delta _ {l}}

the scattering length for s-waves ( ) becomes: ${\ displaystyle l = 0}$

{\ displaystyle a = \ pm \ lim _ {k \ to 0} {\ frac {\ sin \ delta _ {0}} {k}} \ ;.}

literature

Cohen-Tannoudji: Quantum Mechanics - Vol 2, Wiley-Interscience, 2006.

Web links

TU Munich: Properties of the nucleon-nucleon interaction ( Memento from March 7, 2014 in the Internet Archive )