Total4Hephotoabsorption cross section reexamined: Correlated versus effective interaction hyperspherical harmonics

10 April 2001

journal article
research article
Published by American Physical Society (APS) in Physical Review C

Vol. 63 (5) , 057002
https://doi.org/10.1103/PhysRevC.63.057002

Abstract

Two conceptually different hyperspherical harmonics expansions are used for the calculation of the total

^{4} He

photoabsorption cross section. Besides the well-known method of correlated hyperspherical harmonics, the recently introduced effective interaction approach for the hyperspherical formalism is applied. Semirealistic NN potentials are employed and final-state interaction is fully taken into account via the Lorentz integral transform method. The results show that the effective interaction leads to a very good convergence, while the correlation method exhibits a less rapid convergence in the giant dipole resonance region. The rather strong discrepancy with the experimental photodisintegration cross sections is confirmed by the present calculations.

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This publication has 17 references indexed in Scilit:

Modern Nuclear Force Predictions for the $α$ Particle
Physical Review Letters, 2000
Photodisintegration of three-body nuclei with realistic 2N and 3N forces
Physics Letters B, 2000
Contribution of Nucleon-Nucleon $P$ Waves to $nt - nt$ , $dd - pt$ , and $dd - dd$ Scattering Observables
Physical Review Letters, 1999
Low energy n+t scattering and the NN forces
Physics Letters B, 1999
Neutron- ${}^{3}H$ and Proton- ${}^{3}H e$ Zero Energy Scattering
Physical Review Letters, 1998
Is There a Pronounced Giant Dipole Resonance in ${}^{4}H e$ ?
Physical Review Letters, 1997
Response functions from integral transforms with a Lorentz kernel
Physics Letters B, 1994
Elastic photon scattering from ${}^{4}{He}$ : Charge symmetry problem
Physical Review C, 1992
Photoneutron cross section for ${}^{4}{He}$
Physical Review C, 1980
Solution of the Faddeev equations for the triton problem using local two-particle interactions
Nuclear Physics A, 1969