Resonant scattering of isobaricNe19andF

“…This is a time-consuming process and a method was developed to scan in one measurement many resonances by using thick polyethylene targets [24,25]. The radioactive beam loses energy traversing the target: the initial beam energy and target thickness are chosen in order to cover the centre-of-mass energies of interest.…”

“…The radioactive beam loses energy traversing the target: the initial beam energy and target thickness are chosen in order to cover the centre-of-mass energies of interest. The method, widely applied in Louvain-la-Neuve and other RIB facilities [2,25,26,27,28], has been extended to study the ground and excited states of unbound nuclei, either directly or through their isobaric analogue states: for example 11 N [29] and 19 Na [30,31] in Louvain-la-Neuve, 7 He [32] at the TwinSol Facility of the Notre Dame University. In addition, using α particles as a target, the same method was applied to the investigation of the cluster structure of resonances in selected nuclei (section 4.2).…”

“…Depending on the spin assignment the resonance strength estimates vary by almost a factor of 10, but all are considerably lower than the strength of the 13 N(p,γ) 14 O reaction. The resonant scattering in a thick target method described in section 3.1 was first employed to investigate resonances between 650 and 1000 keV [25]. Following this, a series of experiments, all based on the detection of the decay of 20 Na, were performed RIB Physics at the CRC Louvain-la-Neuve 8 in the 1990's where more and more stringent limits were set on the resonant strength of the low-lying resonances in 20 Na [18,36,37].…”

Radioactive ion beam physics at the cyclotron research centre Louvain-la-Neuve

“…This is a time-consuming process and a method was developed to scan in one measurement many resonances by using thick polyethylene targets [24,25]. The radioactive beam loses energy traversing the target: the initial beam energy and target thickness are chosen in order to cover the centre-of-mass energies of interest.…”

“…The radioactive beam loses energy traversing the target: the initial beam energy and target thickness are chosen in order to cover the centre-of-mass energies of interest. The method, widely applied in Louvain-la-Neuve and other RIB facilities [2,25,26,27,28], has been extended to study the ground and excited states of unbound nuclei, either directly or through their isobaric analogue states: for example 11 N [29] and 19 Na [30,31] in Louvain-la-Neuve, 7 He [32] at the TwinSol Facility of the Notre Dame University. In addition, using α particles as a target, the same method was applied to the investigation of the cluster structure of resonances in selected nuclei (section 4.2).…”

“…Depending on the spin assignment the resonance strength estimates vary by almost a factor of 10, but all are considerably lower than the strength of the 13 N(p,γ) 14 O reaction. The resonant scattering in a thick target method described in section 3.1 was first employed to investigate resonances between 650 and 1000 keV [25]. Following this, a series of experiments, all based on the detection of the decay of 20 Na, were performed RIB Physics at the CRC Louvain-la-Neuve 8 in the 1990's where more and more stringent limits were set on the resonant strength of the low-lying resonances in 20 Na [18,36,37].…”

Radioactive ion beam physics at the cyclotron research centre Louvain-la-Neuve

“…We do find consistent results when requiring coincidence neutron detection with RESONEUT, though the efficiency reduces the statistics by a factor of about 30. The reconstructed excitation spectrum in 18 Ne from 17 F+p coincidences (see Fig. 8 in [7]) is dominated by one strong resonance corresponding to the 3 + state in 18 Ne at 4.523 MeV that known to be the strongest resonance in the 17 F(p,γ) 18 Ne reaction [6].…”

“…A 95.5-MeV beam of 17 F from RESOLUT with an intensity of about 3 × 10 4 s −1 bombarded a 0.52 mg/cm 2 CD 2 target. Neutrons from the (d,n) reaction were detected at θ lab = 145 • − 165 • using the RESONEUT array of P-terphenyl scintillators that provided good n − γ discrimination for energies greater than about 50 keV ee [8].…”

Studies of X-ray burst reactions with radioactive ion beams from RESOLUT

11-Sodium