Investigation of Pygmy Dipole Resonance in neutron rich exotic nuclei R.Avigo 1,2, O.Wieland 1, A.Bracco 1,2, F.Camera 1,2 on behalf of the AGATA and DALI2 collaborations 1 INFN, sezione di Milano 2 Università degli studi di Milano
Outlines Pygmy Dipole Resonance E1 strength investigation of 62,64 Fe nuclei with relativistic coulomb excitation PreSPEC-AGATA setup at GSI Preliminary results about 62,64 Fe Next investigation : 70 Ni isotope Conclusions
Pygmy Dipole Resonance in neutron rich nuclei E1 strength response measured in neutron rich stable nuclei accumulation of strength around and above neutron separation energy interpret as a collective motion called Pygmy Dipole Resonance (PDR) Relevant for nuclear structure: neutron skin thickness [PRC 76, 051603(R) (2007)] Journ. of Phys. 580 (2015) 012052 Equation of State (simmetry energy term) [PRC 81,041301(R)(2010)] A lot of open points about PDR: Isoscalar/isovector character Collectivity PLB 738 2014 519-523
Pygmy Dipole Strength in astrophysics Relevant connection with astrophysics: Neutron star structure Radius exstimation [J. Phys.420 012143] Nucleosynthesis Influence on r-process [PRC 91, 044318 (2015)] PLB 436 1998. 10 18
Arb. Un. Iron isotopes γ ray- Strength function measured for 56 Fe Theoretical predictions show dipole strenght around 10 MeV and also below the threshold for 62,64 Fe For the first time E1 strength distribution below the threshold will be studied for exotic isotopes at varying of the neutron number 62 Fe:expected dipole strength 80 62 Fe RPA calculation 40
Relativistic coulomb excitation Relativistic coulomb excitation of Pygmy Dipole Strength High selectivity No neutron-threshold effect Pygmy Dipole Strength measured for the first time in exotic nuclei: 62,64 Fe coulomb excitation experiment in GSI NPA 693, 90 (2001) virtual photon b>bmin γ emission
ΔE (arb. Un.) Relativistic coulomb excitation selection @ GSI Z Identification of beam of interest A/Q Identification of reaction products Scattering angle E (arb. Un.) mrad
PreSPEC-AGATA setup AGATA array provides an high resolution energy in gamma detection, suppression of the doppler broadening and suppression of background 68 22 HECTOR array (LaBr 3 :Ce and BaF 2 scintillator detectors) provides efficiency in a wide range of angles 95 142 AGATA coupled with HECTOR allows to cover a wide angular range This can be used to prove the multipolarity of gamma rays detected In addition backward scintillators can be used for the estimation of background
Counts Counts Low energy spectra @ GSI 20 15 10 10 1 AGATA 64 Fe* 400 600 800 5 GEANT 2 + 877 kev Ground State GEANT 0 400 500 600 700 800 900 1000 1100 1200 1300 1400 E [kev] Thick target and relativistic (440 MeV/nucl.) beam required a fine tuning of PreSPEC and AGATA detectors to observe 2 + state decay for both iron isotopes 2 + 746 kev Ground State B(E2) of 2 + decay is known and it is used as a benchmark to extrapolate B(E1) of high energy state
Counts Counts High energy spectra AGATA 62 Fe* Preliminary AGATA 64 Fe* Preliminary 10 10 1 4000 8000 12000 1 4000 8000 12000 E [kev] E [kev] TARGET PROJECTILE Evaluation of background with backward detectors (target emission predominant respect to projectile) CASCADE code used to evaluate target (red) and projectile (green) statistical decay 142
B(E1) strength [e 2 fm 2 ] B(E1) strength [e 2 fm 2 ] Results about E1 strength 0,40 0,35 0,30 AGATA 62 Fe* B(E1) strength 6-8MeV =1 ± 0.3 e 2 fm 2 0,40 0,35 0,30 AGATA 64 Fe* B(E1) strength 6-8MeV =1.4 ± 0.3e 2 fm 2 0,25 0,25 0,20 0,20 0,15 0,15 0,10 0,10 0,05 0,05 0,00 3000 4000 5000 6000 7000 8000 9000 10000 E [kev] 0,00 3000 4000 5000 6000 7000 8000 9000 10000 E [kev] After background subtraction structures around 6-7 MeV remain. Using the 2 + state decay measurement as a benchmark, it was possible to extract B(E1) from this high energy statistics
Results about E1 strength 1,80 1,70 1,60 1,50 1,40 1,30 1,20 1,10 1,00 0,90 Ratio E2 yield/e1 yield Preliminary 0,80 15 30 45 60 75 Θ(degree) E2-Yield/ E1-Yield Preliminary Preliminary Angular distribution was used to prove the E1 character of states above 6 MeV. The ratio between distribution of statistics from 2 + decay and statistics above 6 MeV was compared with the expected ratio between E2 and E1 emission
Results about E1 strength Sum B(E1) (6-8MeV) Phys. Rev. Lett. 112, 072501 Preliminary B(E1) estimation shows similar trend with summed B(E1) obtained in other papers. The well known challenge of understanding the r-process abundances requires measurements of the E1-strength function especially towards the neutron-drip line
70 Ni measurement @ Riken Experiment at Riken laboratory to measure PDR in 70 Ni with NaI (DALI) and LaBr 3 :Ce detectors Theoretical prediction 2 + state decay already identified soon high energy states 2 + 1260 kev Ground State [PRL 105, 022502 (2010)] E[keV]
Conclusions E1 strenght accumulation at one particle separation energy has attracted interest because it is relevant for both nuclear structure and astrophysics A lot of data available for stable nuclei, data about exotic nuclei very scarce Measurement of E1 response of 64,62 Fe by relativistic coulomb scattering at GSI laboratories First preliminary evaluation of summed B(E1) around one particle separation energy was achieved Interesting data about E1 response of 70 Ni were collected in Riken experiment
Thank you for your kind attention
Counts High Energy gamma rays 100 AGATA 62 Fe* Preliminary 10 GEANT 1 4000 8000 12000 E [kev] The width of structures at high energies is consistent with energy resolution of AGATA
PreSPEC-AGATA setup AGATA PreSPEC setup in GSI laboratory allows to produce radioactive beams at relativistic energies and select in flight the isotopes of interest (FRS) The LYCCA calorimeter allows to select the product of reaction on secondary target EPJ Web of Conferences 66, 02083 (2014) AGATA array provides an high resolution energy in gamma detection, suppression of the doppler broadening and suppression of background HECTOR array (LaBr3:Ce and BaF2 scintillator detectors) provides efficiency in a wide range of angles