Λ spin-orbit splitting deduced from DWIA analysis of the 89Y(π+,K+) Λ89Y reaction T. Motoba (Osaka E-C U.) D.J. Millener (Brookhaven N.L.) D. Lanskoy (Moscow State U.) Y. Yamamoto (Tsuru U.)
Λ spin-orbit splitting deduced from DWIA analysis of the 89 Y (π +,K + ) Λ 89 Y reaction T. Motoba (Osaka E-C U.) D.J. Millener (Brookhaven N.L.) D. Lanskoy.
Dec 21, 2015
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Λ spin-orbit splitting deduced from DWIA analysis of
the 89Y(π+,K+) Λ89Y reaction
T. Motoba (Osaka E-C U.)
D.J. Millener (Brookhaven N.L.)
D. Lanskoy (Moscow State U.)
Y. Yamamoto (Tsuru U.)
(π+,K+) reaction characteristics
T.Motoba, H. Bando, R. Wunsch, J.Zofka, Phys. Rev.C38 (1988)
H. Hotchi et al,
Phys. Rev. C64
044302 (2001).
Great achievement
good resolution
Γ=1.65 MeV
Ls splitting (ΔE):
(f )=1.70 MeV
(d)=1.63
(p)= 1.37
High resolution γ-ray
mesurements
How to understand “large” splitting of subpeaks observed in heavy systems
ΔE is not proportional to (2l+1)
XS ratio is determined as
EXP vs. DWIA CAL(WS, VLS=4.3MeV)
Take core-excited states seriously : up to the level of p-shell
hypernuclei
CONCLUSION (1)Reproduce cross section ratios among a series of pronounced peaks and sub-peaks.
CONCLUSION(2) Observed energy sp
acing between doublet like sub-peaks
(3L-3R) are reproduced with δ(f)=0.20 MeV,
which leads to δ(d)=0.15 MeV and δ(p)=0.09 MeV.
(cf. Λ 13 C:δ(p)=0.152+-0.07 MeV)
CONCLUSION
(3) even the GS peak should consists of two components. (See the exp. GS peak The present analysis leads to the prediction that.)
CONCLUSION (4) Right partner(s) contain parity-mixing
contributions :example for 3R: [1p1/2f7/2hole] Λ ( d3/2 )
New insight into (π+,K+) spectra for other medium-heavy hypernuclei
END
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