1 / 15

Study of the Tensor Correlation in Oxygen Isotopes using Mean-Field-Type and Shell Model Methods

Study of the Tensor Correlation in Oxygen Isotopes using Mean-Field-Type and Shell Model Methods. Satoru Sugimoto Kyoto University 1. Introduction 2. Charge- and parity-projected Hartree-Fock method (a mean field type model) and its application to sub-closed shell oxygen isotopes

indira-avery
Download Presentation

Study of the Tensor Correlation in Oxygen Isotopes using Mean-Field-Type and Shell Model Methods

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. Study of the TensorCorrelation in OxygenIsotopesusing Mean-Field-Type and Shell Model Methods Satoru Sugimoto Kyoto University 1. Introduction 2. Charge- and parity-projected Hartree-Fock method (a mean field type model) and its application to sub-closed shell oxygen isotopes 3.Shell model calculation to 15,16,17O 4. Summary

  2. Introduction • The tensor force is important in nuclear structure. • There remain many open problems to be solved. • How does the tensor correlation change in neutron-rich nuclei? • Shell evolution (Ostuka, PRL 95 232502 (2005)). • The breakdown of the magic number in 11Li (Myo et al.) • The relation to the ls splitting in 5He (Myo et al. PTP 113 (2005) 763)

  3. The correlation to be included 2p-2h correlation • In the simple HF calculation, 2p-2h correlations are hard to be treated. • We need to include at least 2p-2h correlations to exploit the tensor correlation.beyond mean field model cf. Single-particle (H-F) correlation

  4. Charge- and parity-symmetry breaking mean field method • Tensor force is mediated by the pion. • Pseudo scalar (s) • To exploit the pseudo scalar character of the pion, we introduce parity-mixed single particle state. (over-shell correlation) • Isovector (t) • To exploit the isovector character of the pion, we introduce charge-mixed single particle state. • Projection • Because the total wave function made from such parity- and charge-mixed single particle states does not have good parity and a definite charge number. We need to perform the parity and charge projections. Refs. Toki et al., Prog. Theor. Phys. 108 (2002) 903. Sugimoto et al., Nucl. Phys. A 740 (2004) 77; ; nucl-th/0607045. Ogawa et al., Prog. Thoer. Phys. 111 (2004) 75; Phys. Rev. C 73 (2006) 034301.

  5. Results for 16O • MV1(VC)+G3RS(VT,VLS) • By performing the parity and charge projection the potential energy from the tensor force becomes sizable value.

  6. d3/2 p1/2 d5/2 s1/2 p3/2 VT and VLS per particle • The potential energy from the tensor force has the same order in magnitude as that from the LS force. • The tensor potential energy decreases as neutron numbers.

  7. Wave function(16O, xT=1.5) s1/2 proton dominant Opposite parity components mixed by the tensor force have narrow widths. It suggests that the tensor correlation needs high-momentum components.

  8. Mixing of the opposite parity components in single-particle states • If a next j=1/2 orbit is occupied newly, the mixing probabilities of the j=1/2 orbit reduce by ablocking effect. • Mixing of the opposite-parity component may affect excitation spectra of nuclei. 0p1/2 1s1/2

  9. Shell model calculation • We perform the shell model calculation including 1p-1h and 2p-2h configurations to study the tensor correlation. • inclusion of narrow-width single-particle wave functions • The shell model calculation can treat the correlation which cannot be treated in a mean-field-type calculation. cf. Myo et al. PTP 113 (2005) 763

  10. Model space • 16O: (0p-0h)+(1p-1h)+(2p+2h)17O: (1p-0h)+(2p-1h)+(3p+2h)15O: (0p-1h)+(1p-2h)+(2p+3h) • Core (hole state) • (0s1/2)4(0p3/2)6(0p1/2)4 • Harmonic oscillator single-particle wave functions • Particle state • Harmonic oscillator single-particle wave functions+Gaussian single-particle wave functions with narrow (half) width parameters • These are ortho-normalized by the G-S method

  11. Effective interaction • Central force: Volkov No. 1 • A.B. Volkov, Nucl. Phys. 74 ( 1965 ) 33 • Tensor: Furutani force • H. Furutani et al., Prog. Theor. Phys. Suppl. 68 ( 1980 ) 193 • LS: G3RS • . Tamagaki, Prog. Theor. Phys. 39 ( 1968 ) 91 • No Coulomb force

  12. 16O • HO: (1s 0d)+(1p 0f)+(2s 1d 0g) • NWG: bNW = bHO/2 = 1.8 fm • d-orbit: (1s 0d)+sNW+pNW+dNW • f-orbit: (1s 0d)+sNW+pNW+dNW+fNW • By including single-particle orbits with narrow width parameters the correlation energy from the tensor force becomes large.

  13. 17,15O (NWG (up to f-orbit)) • DKE+DVC+DVT≈0 • ls-splitting nearly equals to DVLS 17O 15O

  14. Magnetic Moment • Magnetic moments change a little in spite of the large correlation energy form the tensor force. A=17 A=15

  15. Summary • We apply a mean-field model which treats the tensor correlation by mixing parities and charges in single-particle states (the CPPHF method) to oxygen isotopes. • The opposite parity components induced by the tensor force is compact in size. (high-momentum component) • We perform the shell model calculation up to 2p-2h states to 15,16,17O. • The tensor correlation energy becomes large by including Gaussian single-particle wave functions with narrow widths. • The tensor correlation changes ls splitting and magnetic moments in 15,17O a little in spite of its large correlation energy.

More Related