Abstract
A large set of cross-section data for the H-1 (d,pp)n breakup reaction was measured at 130 MeV deuteron beam energy with the Germanium Wall setup covering the range of very forward polar angles. In the investigated part of the phase-space, the dynamics is dominated by the Coulomb force influence. The data are compared with results of theoretical calculations based on the realistic Argonne V18 potential supplemented with the long-range electromagnetic component. The predictions also include the Urbana IX three nucleon force model. The cross-section data reveal seizable Coulomb force effects.
Highlights
New-generation experiments dedicated to investigations of the p(d, pp)n breakup reaction in a large phase-space region were performed with the use of the SALAD and BINA detectors at KVI [1,2,3,4]
The Coulomb force was implemented into calculations with the realistic Argonne V18 (AV18) nucleon–nucleon (N N ) potential combined with the Urbana IX (UIX) three nucleon force (3N F) model [6]
The experiments at FZJ was conducted with the Germanium Wall (GeWall) setup [7] at the deuteron beam energy of 130 MeV
Summary
New-generation experiments dedicated to investigations of the p(d, pp)n breakup reaction in a large phase-space region were performed with the use of the SALAD and BINA detectors at KVI [1,2,3,4]. They revealed for the first time large Coulomb force effects in the breakup cross-section data [2]. A dedicated experiment [7] was performed at the Research Center in Jülich (FZJ) aiming at investigation of the Coulomb force effects at the very forward angular region. The results of the following experiment at FZJ dedicated to cross-section measurement are presented
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