Three-body continuum energy correlations in Borromean halo nuclei. II

Abstract: The general properties of intrinsic energy correlations in the three-body continuum of Borromean halo nuclei are considered. A model that describes the system as a three-body α + n + n cluster structure and reproduces the experimentally known properties of 6 He and 6 Li is used to study low-lying resonances and soft modes. The intrinsic correlated structure of the 6 He continuum reveals a unique structure for three-body 2 + 1 , 2 + 2 , and 1 + 1 resonances and a lack of resonant structure in soft dipole and mo… Show more

“…One can expect four main physical sources for amplification of transitions, partly in correspondence with the possible amplification of cross sections for 3 → 3 scattering [3]: (i) True three-body resonances, which are due to interaction of all three particles in the interior domain; (ii) A long lived binary resonance in one of the constituent pairs; (iii) The response of an extended system to long-range transition operators used to excite the continuum; (iv) Resonances due to strong coupling between channels (CC resonance in a few channels) or a parametric resonance in quantum diffusion with complex coefficients [20,21].…”

“…[2] and [3] we summarized the Jacobi spatial x, y and relative momentum k x , k y coordinates necessary to describe the bound and scattering states of three-body systems consisting of a spinless core and two halo nucleons. We henceforth use the same notations for our three-body wave functions and all variables.…”

“…The earliest articles [1] examined simple transition responses, summed over all final states. More recently we have studied general features of the spatial two-dimensional densities [2] and intrinsic energy correlations in 3 → 3 scattering [3], again exemplified by the continuum of 6 He. Three-body core+n + n dynamics and the Schrödinger threebody equation, solved within the method of hyperspherical harmonics (HH) (see Refs.…”

“…Three-body core+n + n dynamics and the Schrödinger threebody equation, solved within the method of hyperspherical harmonics (HH) (see Refs. [1][2][3][4][5]), were used consistently for both bound and continuum states. For 6 He a 'realistic' αn interaction [1,4] with purely repulsive s-wave component and the GPT nn interaction [6] were used.…”

“…acts as a filter. Also, in contrast to transitions from compact bound states, the range of impact parameters acceptable in 3 → 3 scattering is limited by a maximal hypermoment K < 2mE/h 2 ρ where E is the continuum energy, m the nucleon mass and ρ 2 = (A c +2)R is the rms hyperradius of the bound state expressed via rms radii of the core (R A c ) and of the halo nucleus (R A c +2 ) [14], and is also the three-body impact parameter in the 3 → 3 scattering case [3]. The difference between the intrinsic structure of the continuum and responses is most dramatically seen if the binary interactions are set to zero for the continuum wave functions: this is the no-final-state-interaction (NoFSI) case often used for estimates.…”

Three-body continuum energy correlations in Borromean halo nuclei. III. Short-range external fields

“…One can expect four main physical sources for amplification of transitions, partly in correspondence with the possible amplification of cross sections for 3 → 3 scattering [3]: (i) True three-body resonances, which are due to interaction of all three particles in the interior domain; (ii) A long lived binary resonance in one of the constituent pairs; (iii) The response of an extended system to long-range transition operators used to excite the continuum; (iv) Resonances due to strong coupling between channels (CC resonance in a few channels) or a parametric resonance in quantum diffusion with complex coefficients [20,21].…”

“…[2] and [3] we summarized the Jacobi spatial x, y and relative momentum k x , k y coordinates necessary to describe the bound and scattering states of three-body systems consisting of a spinless core and two halo nucleons. We henceforth use the same notations for our three-body wave functions and all variables.…”

“…The earliest articles [1] examined simple transition responses, summed over all final states. More recently we have studied general features of the spatial two-dimensional densities [2] and intrinsic energy correlations in 3 → 3 scattering [3], again exemplified by the continuum of 6 He. Three-body core+n + n dynamics and the Schrödinger threebody equation, solved within the method of hyperspherical harmonics (HH) (see Refs.…”

“…Three-body core+n + n dynamics and the Schrödinger threebody equation, solved within the method of hyperspherical harmonics (HH) (see Refs. [1][2][3][4][5]), were used consistently for both bound and continuum states. For 6 He a 'realistic' αn interaction [1,4] with purely repulsive s-wave component and the GPT nn interaction [6] were used.…”

“…acts as a filter. Also, in contrast to transitions from compact bound states, the range of impact parameters acceptable in 3 → 3 scattering is limited by a maximal hypermoment K < 2mE/h 2 ρ where E is the continuum energy, m the nucleon mass and ρ 2 = (A c +2)R is the rms hyperradius of the bound state expressed via rms radii of the core (R A c ) and of the halo nucleus (R A c +2 ) [14], and is also the three-body impact parameter in the 3 → 3 scattering case [3]. The difference between the intrinsic structure of the continuum and responses is most dramatically seen if the binary interactions are set to zero for the continuum wave functions: this is the no-final-state-interaction (NoFSI) case often used for estimates.…”

Three-body continuum energy correlations in Borromean halo nuclei. III. Short-range external fields

Energy levels for He-6 (Helium-6)

Excited Nuclear States for He-6 (Helium)