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Study of Light Hypernuclei by Pionic Decay at JLAB

Study of Light Hypernuclei by Pionic Decay at JLAB. Liguang Tang Other spokespersons: A. Margaryan, L. Yuan, S.N. Nakamura, J. Reinhold Collaboration: From both Hall C and A hypernuclear programs JLAB PAC 33, January 14-18, 2008. n (udd). P (uud).  (uds).  (uds). n. N.R. N.R.

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Study of Light Hypernuclei by Pionic Decay at JLAB

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  1. Study of Light Hypernuclei by Pionic Decay at JLAB Liguang Tang Other spokespersons: A. Margaryan, L. Yuan, S.N. Nakamura, J. Reinhold Collaboration: From both Hall C and A hypernuclear programs JLAB PAC 33, January 14-18, 2008

  2. n (udd) P (uud)  (uds)  (uds) n N.R. N.R. S.H. S.H. p N.R. S.H. S.H.  D.H. D.H.  D.H. Introduction • Nuclei Baryon-Baryon Interaction Neutron Stars S=-2 S=-1 S=-0 The single and double hypernuclei are the main sources of the strange sector of baryon-baryon interaction

  3. Discovery of the first hypernucleus by pionic decay in emulsion produced by Cosmic Rays. Marian Danysz and JerzyPniewski, 1952 •   p + - (64%);   n + 0 (36%) • Remain effective even at medium A Access rich information about hypernuclear and nuclear physics Used exclusively to determine the binding energy of light (A≤15) hypernuclei in emulsion Precision: ~50keV Resolution: ~0.5 – 1.0 MeV Problems: - Poor statistics - Calibrations - Cannot resolve pure 2-body decay Was not interested in the past ~20 years – low energy and low yield

  4. New Opportunity at JLAB • Combination the CEBAF beam and the HKS system • High precision and high yield • Program features: • Energy resolution: ~130 keV FWHM • B precision: ~10 keV • Simultaneous lifetime measurement (timing resolution ≤80ps) • Wide range of physics

  5. Directly Produced Hypernuclei - Example e’ K+ 12C Ground state doublet of 12B B and  e p 12B 2- ~150 keV  1- 0.0 - 12Cg.s. Mesonic two body decay

  6. Indirectly Produced Hypernuclei – ExampleFragmentation Process Access to variety of light and exotic hypernuclei, some of which cannot be produced or measured precisely by other means e’ K+ 12C e p 12B*   4H -  Mesonic two body decay (~10-10s)  Fragmentation (<10-16s) 4He

  7. Physics Objectives – YN Interactions The wealth of information coming from this poor statistics emulsion experiment is solely attributable to the technique's inherent good energy resolution, ~50 keV in this instance, and forcefully emphasizes the need to strive for comparable energy resolution in counter experiments. - D. Davis, 1992 As it turns out, binding energies of light hypernuclei are highly correlated from calibrations to 12C for example, and most likely incorrect. - D. Davis, HYP2006 Emulsion data of light hypernuclei (primarily the ground states) were used to check theoretical models on YN interaction in the past 40 some years. Problem of inconsistency and model of choice exist Recent -spectroscopy program has been successful for spin dependent interactions but unable to measure B Recent successful mass spectroscopy programs cannot reach a precision on B exceeding emulsion data

  8. YN Interactions – cont. Replace emulsion data with a new set of data that has a factor of 2-5 times better precision on B to check current and future theories with stringent limits Separate small ground state doublets Study charge symmetry breaking in YN interaction, such as B(4Hg.s.) - B(4Heg.s.)

  9. Search for Highly Exotic Hypernuclei • Search for light hypernuclei toward nucleon drip-lines: hypernuclei with extreme isospins • Other programs: • Heavy ion collision • JINR, HypHI • This program – high precision on B Hypernuclei at: * -stability line * Neutron rich * Nucleon drip-lines  Bound hypernucleus Search for and measure precisely the B of the exotic hypernuclei is another effective way for exotic nuclear physics Many hypernuclei with unstable nuclear core exist, e.g. 6He, 7Be, 8He, 9Be. Other exotic hypernculei may exist, e.g. 6H, 7H, 8H, 10He, and 11Lithrough fragmentation process

  10. Impurity Nuclear Physics Hypernuclear and nuclear structure Hypernucleus w/ hyperfine g.s. doublet Hypernucleus at g.s.  E < 100 keV - E < 100 keV Decay pion can be used to determine the spin ordering of the doublet Nucleus at g.s. Nucleus w/ hyperfine g.s. doublet Pion decays offer insights into the hypernuclear and nuclear structure, and the momentum dependence of the single particle wave functions

  11. Impurity Nuclear Physics – cont.Probing nuclear structure with  Example: 7Li w/ g.s. doublet 1/2+ & 3/2+

  12. Impurity Nuclear Physics – cont.Probing nuclear structure with  Example: 10B w/ g.s. doublet 1- & 2- Spin order is not known  transition (2-  1-) was not found Success competition by weak mesonic decay Assumed order could be wrong Decay pion may provide clearification 10Be may be the candidate at JLAB

  13. Impurity Nuclear Physics Role and effect of  in Nucler Medium 7Li 11C E2 7He 11B   - - 1/2+ 5/2+ ~1 .48 ~1 .7 3/2+ E2 E2 7/2+ ~0 .26 1/2+ 0 (MeV) 5/2+ 0 (MeV) 5/2+ and 3/2+ states are from unbound 2+ state of 6He core Precise Ballows separation of those low lying states which have sufficient long lifetime (i.e.  decay competes with weak decay) Lifetime of these separable states allows to extract transition probabilities B(E2) and B(M1) which provide information about the medium effect to baryon or  to the core medium

  14. Tagged-Weak Pi-Method of B(E2) and B(M1) Measurement If states can be separated and statistics is sufficient to measure lifetimes, then By measuring both of PBweak(t) and PAweak(t) and fitting them together to the equations above, , and m can be determined.

  15. Technique & Exp. Layout Need calibration for the absolute HS central momentum Standard Splitter and HKS for K+ Enge & target moved upstream for decay pions Tilted TGT (25mg/cm2) Eff. TGT (50mg/cm2) Standard pre-chicane beam line (E05-115) Local dump for photons Similar luminosity as E05-115 (HKS/HES)

  16. Parameters of the HS spectrometer Configuration Enge Split-Pole (or HES) spectrometer and detector package Central momentum 115 MeV/c Momentum acceptance ± 40% Momentum resolution (r.m.s.) 10-4 without multiple scattering Momentum resolution (r.m.s.) 4.9 10-4 with multiple scattering Dispersion 1.28 cm/% Time-zero precision < 100 ps (~80 ps) Pion detection angle ~60 degree relative to the incident beam Flight path length 309 cm - survival rate ~ 60% Solid angle ~20 msr Total efficiency of the detector package ~80%

  17. Example of Possible G.S. of Light Hypernucleifrom 12C Target 5He • Background: • ~97.5% QF  decay • ~2.5% (K+ & -) accidentals 8Li 12B 7Li 9Be 4H 8Be 11B 3H G.S. only (doublet structures are not shown) Estimated based on emulsion data thus may under-estimated for some of the hypernuclei Additional hypernuclei may appear

  18. Beam Parameters and Beam Time • Targets: 12C and 7Li (Optimized combination) • 12C – Heaviest in p-shell; reliable yield rates on variety of light hypernuclei but not too crowded • 7Li – Best chance for the lightest and highly exotic hypernuclei, such as 6H • Beam energy: 1.8 – 2.2 GeV • Beam current and acq. time • 12C, 60A (100 Max.), 20 days • ~1000 counts for 4H (physics w/ moderate yield) • ~6000 counts for 5He (physics and calibration) • 7Li, 30A (50 Max.), 20 days Primary: 7He, 6He, 5He; Questionable:4He, 6H, 5H, 4H • Trigger rate: ~ few hundred Hz

  19. Summary CEBAF beam and HKS provide unique opportunity for a new counter type high precision decay pion program – Producing data that replaces emulsion data in the role of checking theories It can study a wide range of physics that either not accessible by other means or complementary to other programs

  20. International Hypernuclear Network • PANDA at FAIR • 2012~ • Anti-proton beam • Double -hypernuclei • -ray spectroscopy • SPHERE at JINR • Heavy ion beams • Single -hypernuclei • HypHI at GSI/FAIR • Heavy ion beams • Single -hypernuclei at • extreme isospins • Magnetic moments • MAMI C • 2007~ • Electro-production • Single -hypernuclei • -wavefunction • JLab • 2000~ • Electro-production • Single -hypernuclei • -wavefunction • FINUDA at DANE • e+e- collider • Stopped-K- reaction • Single -hypernuclei • -ray spectroscopy • (2012~) • J-PARC • 2009~ • Intense K- beam • Single and double -hypernuclei • -ray spectroscopy for single  • JLab, HπS • Electro-production • Single -hypernuclei at • normal and extreme isospins • Binding energies • π - decay spectroscopy • Impurity nuclear physics Basic map from Saito, HYP06

  21. Introduction – cont. Example Time delayed • Decay -is used even in modern studies • In the last 20 years or so, mesonic decay has not been really interested in study of the hypernuclear/nuclear structure, because of its low momentum and the difficulty to reach high precision with unavoidable thick targets using msonic beams • Emulsion: cannot resolve two body decay and typical resolution is 0.5 – 1.0 MeV • Counter type: resolution is 1.0 – 2.0 MeV H. Outa et al., “Lifetime measurement of 4H hypernucleus”, INS-Rep.-914 (1992)

  22. The proposed project capable to provide precise binding values of known hypernuclei and have a great potential to extend this landscape

  23. Exotic Hypernuclei Different decay channels of excited 7He* hypernucleus (Majling, 2006).

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