6533b870fe1ef96bd12cf1ff
RESEARCH PRODUCT
Role of Levinson’s theorem in neutron-deuteron quartetS-wave scattering
E. O. AltE. O. AltH. FiedeldeyS. A. SofianosA. Papastylianossubject
Elastic scatteringPhysicsMany-body problemNuclear and High Energy PhysicsSingularityScatteringQuantum mechanicsInverse scattering problemBound stateSupersymmetryScattering theorydescription
The real part of the phase shift for elastic neutron-deuteron scattering in the quartet {ital S} wave channel, as calculated with the exact three-body theory, assumes at threshold the value {pi} if normalized to zero at infinity; that is, it does not comply with the expectations raised by a naive application of Levinson's theorem since no bound state exists in this channel. A description of this situation on an equivalent two-body level via a potential, constructed by means of the Marchenko inverse scattering theory, necessitates the introduction of a fictitious bound state. This predominantly attractive, equivalent local potential can be related via supersymmetry to a strictly phase equivalent partner potential. The latter is unique and purely repulsive, a behavior already exhibited by the underlying exact effective neutron-deuteron interaction. At the origin it possesses a singularity of the centrifugal barrier-type which admits of the required zero-energy phase shift value of {pi} by means of a modified version of Levinson's theorem. Hence, the unphysical bound state of the attractive equivalent local potential plays a role in three-body scattering theory analogous to the one of a Pauli-forbidden state in the context of the resonating group method.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 1990-08-01 | Physical Review C |