1 / 19

Deformation Effects on N=7 Halo Nuclei Structures

Explore the deformation effects on N=7 halo nuclei structures through mean-field calculations and investigate properties like halo structure and parity inversion. Utilize SHF models and Glauber-model calculations for understanding these exotic nuclear systems.

mlinn
Download Presentation

Deformation Effects on N=7 Halo Nuclei Structures

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Deformation effects on the structures of the N=7 halo nucleiFurong Xu, Junchen PeiSchool of Physics, Peking University Introduction Calculations for the N=7 isotones Summary

  2. I. Introduction Parity inversion • H.D. Wilkinson and D.E. Ablburger, Phys. Rev. 113, 563 (1959); From the observedβdecay of 11Be, the nucleus might have an ½+ ground state. • In the next year, Talmi and Unna demonstrated that this possibility with shell-model systematics; • Later on, the levels of ½+ and ½- states were well established experimentally. e.g. J.P. Deutsch et al., PLB 268, 178 (1968)

  3. mean-field scheme of neutron levels ½+[211] 2s1/2 5/2+[202] 1d5/2 ½+ 3/2+[211] N=8 ½+[220] ½- 1p1/2 ½-[101] 3/2-[101] 1p3/2 ½-[110] β2=0.3

  4. In 1991, reaction cross section of 11Be was measured to suggest neutron-halo; M. Fukuda et al., PLB 268, 339 (1991) • Parity inversion ( ½+, ½-), halo structure, very strong E1 transition from ½- to ½+ states. interesting! • In the past ~15 years, a lot of works on 11Be; Projected Hartree-Fock, Skyme-Hartree-Fock, Variational shell model, coupled channel, RMF…

  5. Variational shell model (configuration mixing calculations) T. Otsuka, N. Fukunishi, H. Sagawa, PRL70, 1385(1993) Mean field valid? very large β2 deformation? 10Be, β2 ~ 0.67 from B(E2, 2+→0+)=52 (6) e2fm2 ?

  6. II. Investigation of the N=7 isotones

  7. Deformed SHF with the adiabatic blocking of the odd neutron. • Blocking ½+ [220] (the lowest level in sd shell) ½+ • Blocking ½-[101] (the highest level in p shell) ½-

  8. surface pairing volume-pairing mixture-pairing Surface pairing component is important for exotic nuclei J. Dobaczewski et al., EPJA 8, 59 (2000).

  9. SHF without pairing X.Li and P.-H.Heenen, PRC 54,1617(1996) Very flat minima very soft shapes

  10. 晕态

  11. Deformations All ½- states have spherical shapes; For the ½+ state: 11Be: β2 ~ 0.98 13C: β2 ~ 0.5 15O: β2 ~ 0.0 9He: Very soft shapes Significant vibrational effect; Core-vibration mixture; Energy could be sensitive to the effects, but density would not

  12. To understand halo structure: Calculate <l2> If 1d5/2 (l=2), <l2>=6, halo? 9He 11Be 13C <l2>: 0.2 2.6 3.7 mixture of 2s1/2 halo

  13. mean-field scheme of neutron levels ½+[211] 2s1/2 5/2+[202] mixing 1d5/2 ½+ 3/2+[211] N=8 ½+[220] ½- 1p1/2 ½-[101] 3/2-[101] 1p3/2 ½-[110] β2=0.3

  14. Glauber-model calculations of cross sections for 11Be (1/2+) 33 A MeV Expt.Cal.11Be+12C1.561.98311Be+27Al2.272.73413C+12C1.361.43413C+27Al1.911.717790 A MeV11Be+12C0.9421.15611Be+27Al1.381.68

  15. Summary • For N=7 isotones, the ½+state may polarize the nuclei to be largely deformed. • Mean-field calculations cannot understand the parity inversion that would be beyond mean field. • Other properties, such as halo structure, can be obtained by mean field models. To be published in Nucl. Phys. A

  16. Thank you

More Related