Study of 3he(e,e') Longitudinal Response Functions with the Integral-Transform Method
Abstract
The method of integral transforms is first applied for studying the 3He longitudinal response functions. The transforms are calculated from localized bound-state-type solutions to an inhomogenous Schr\"odinger-type three-body equation. Several versions of local s-wave spin-dependent potentials supplemented with a singlet p-wave potential and with the proton-proton Coulomb interaction are used as a two-nucleon input. The conventional charge density operator is utilized. The three-body equations are solved with a high acuracy. It is found that the contribution of the T=3/2 final states to the problem is suppressed and it amounts about 15\%. This might be ascribed to symmetry requirements. The contributions of the p-wave NN interaction and of the Coulomb interaction are found to amount several per cent. Uncertainty due to different choices of s-wave NN forces is of a similar magnitude provided that the low-energy NN data are properly described. The results are compared with the integral transforms of the experimental response functions. For q=300 MeV/c experimental and theoretical results coincide within their uncertainties. For q=500 MeV/c a noticeable difference is detected.
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