Evidence for virtual Δ++ knock-out from 9Be by 1 GeV protons

“…The width of a free isobar is about 120 MeV, which corresponds to a lifetime on the order of 10 -23 s. A virtual isobar is formed in a nucleus outside the mass surface; therefore, the main mode of decay of a free isobar, N   , accompanied by emission of a pion, is forbidden for it, which increases its lifetime in the nucleus. According to theoretical estimates [3-5] and the experimental data available at the present time [6][7][8][9][10], the admixture of isobar configurations in the ground state of the p-shells of nuclei calculated per nucleon amounts to several percent.…”

Isobar Configurations in the Ground State of Nuclei. Effective Polarization of an Isobar

“…The width of a free isobar is about 120 MeV, which corresponds to a lifetime on the order of 10 -23 s. A virtual isobar is formed in a nucleus outside the mass surface; therefore, the main mode of decay of a free isobar, N   , accompanied by emission of a pion, is forbidden for it, which increases its lifetime in the nucleus. According to theoretical estimates [3-5] and the experimental data available at the present time [6][7][8][9][10], the admixture of isobar configurations in the ground state of the p-shells of nuclei calculated per nucleon amounts to several percent.…”

Isobar Configurations in the Ground State of Nuclei. Effective Polarization of an Isobar

“…The probability of the admixture of these exotic nuclear configurations is low because of a low nuclear density and a large isobar-nucleon mass difference. Attempts to detect the manifestation of the ∆-isobar configurations in the ground state of light nuclei were undertaken in series of experiments on nuclei with knockout of ∆-isobars initially present in the nuclei [7][8][9][10][11]. In this case, the reactions with knockout of a ++ ∆ isobar and its subsequent decay into the p + π -system with charge +2 are of interest to us.…”

Momentum distribution of Δ-isobars in light nuclei with closed shells

“…Nuclear reactions that cannot be explained within a model that assumes a single interaction of a projectile particle with bound nucleons of a nucleus are an efficient tool in experimentally studying isobar degrees of freedom in the ground states of nuclei. As an example, we can indicate (π + , π − p) reactions [5,6], where the charged state of a scattered particle changes by 2e, or (p, p ′ π + p) [7] and (γ, π − n) reactions accompanied by the production of particles whose total electric charge is +2 or −1. Such experimental data are usually interpreted, using the model of the quasifree knockout of the isobar [5][6][7][8][9].…”

Isobar configurations: ΔN correlations versus the independent particle model