1 / 26

Zebo Tang University of Science and Technology of China (USTC)

Hypernucleus production at RHIC. Introduction and Motivation Evidence for first antihypernucleus and signal ( for discovery ) Mass and lifetime measurement Production rate and ratios Yields as a measure of correlation ( coordinate and momentum space)

menefer
Télécharger la présentation

Zebo Tang University of Science and Technology of China (USTC)

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. Hypernucleus production at RHIC • Introduction and Motivation • Evidence for first antihypernucleus • and signal (for discovery) • Mass and lifetime measurement • Production rate and ratios • Yields as a measure of correlation (coordinate and momentum space) • A case of low energy scan • Conclusion and Outlook Zebo Tang University of Science and Technology of China (USTC) CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  2. What are hypernuclei(超核)? Nucleus which contains at least one hyperon in addition to nucleons. Hypernuclei of lowest A • Y-N interaction: a good window to understand the baryon potential • Binding energy and lifetime are very sensitive to Y-N interactions • Hypertriton: DB=130±50 KeV; r~10fm • Production rate via coalescence at RHIC depends on overlapping wave functions of n+p+Lin final state • Important first step for searching for other exotic hypernuclei (double-L) The first hypernucleus was discovered by Danysz and Pniewski in 1952. It was formed in a cosmic ray interaction in a balloon-flown emulsion plate. M. Danysz and J. Pniewski, Phil. Mag. 44 (1953) 348 No one has ever observed anyantihypernucleus CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  3. S=-2 S=-1 S=-0 From Hypernuclei to Neutron Stars • hypernuclei L-B Interaction Neutron Stars Saito, HYP06 Several possible configurations of Neutron Stars • Kaon condensate, hyperons, strange quark matter Singleand doublehypernuclei in the laboratory: • study thestrange sectorof the baryon-baryon interaction • provide info on EOS of neutron stars J.M. Lattimer and M. Prakash, "The Physics of Neutron Stars", Science 304, 536 (2004) J. Schaffner and I. Mishustin, Phys. Rev. C 53 (1996): Hyperon-rich matter in neutron stars CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  4. Can we observe hypernuclei at RHIC? • Low energy and cosmic ray experiments (wikipedia): • hypernucleus production via • L or Kcapture by nuclei • the direct strangeness exchange reaction hypernuclei observed • energetic but delayed decay, • measure momentum of the K and p mesons • In high energy heavy-ion collisions: • nucleus production by coalescence, characterized by penalty factor. • AGS data[1] indicated that hypernucleus production will be further suppressed. • What’s the case at RHIC? [1] AGS-E864, Phys. Rev. C70,024902 (2004) CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  5. STAR Detector MTD (BNL LDRD) EMC barrel MRPC ToF barrel 100% for run 10 EMC End Cap FMS FPD TPC Only TPC for this analysis PMD Complete Ongoing DAQ1000 Take data HFT FGT R&D CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  6. Light nuclei at STAR STAR, arXiv:0909.0566 Clearly identified using dE/dx (TPC) Plentiful of light (especially anti)-nuclei RHIC: the best antimatter machine! CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  7. Hyperon at STAR Spatial resolution w/o silicon (TPC only): Primary vertex: few hundred mm in Au+Au Secondary vertex: few mm Secondary vertex finding technique STAR PRL 89 (2002) 132301 Excellent capability for strange particle reconstruction CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  8. Data-set and track selection 3LH mesonic decay, m=2.991 GeV, B.R. 25%; • Track quality cuts, global track • nFitsPts > 25 nFitsPts/Max > 0.52 • nHitsdEdx > 15 • Pt > 0.20, |h| < 1.0 • Pion n-sigma (-2.0, 2.0) • DCA of v0 to PV < 1.2 cm • DCA of p to PV > 0.8 cm • DCA of p to 3He < 1.0 cm • Decay length > 2.4 cm • Data-set used, Au+Au 200 GeV • ~67M Run7 MB, • ~23M Run4 central, • ~22M Run4 MB, • |VZ| < 30cm CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  9. 3He & anti-3He selection • Select pure 3He sample: -0.2<Z<0.2 & dca <1.0cm & p >2 GeV • 3He: 2931(MB07) + 2008(central04) + 871(MB04) = 5810 • Anti-3He: 1105(MB07) + 735(central04) + 328(MB04) = 2168 CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  10. A candidate event at STAR Run4 (2004) 200 GeV Au+Au collision CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  11. signal from the data STAR Preliminary • background shape determined from rotated background analysis; • Signal observed from the data (bin-by-bin counting): 157 ± 30 ; • Projection on antihypertriton yields: constraint on antihypertriton yields without direct observation CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  12. signal from the data STAR Preliminary • Signal observed from the data (bin-by-bin counting): 70±17; • Mass: 2.991±0.001 GeV; Width (fixed): 0.0025 GeV; CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  13. Combined signals Combine hypertriton and antihypertriton signal: 225±35 STAR Preliminary This provides a >6s signal for discovery CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  14. Lifetime STAR Preliminary STAR Preliminary • Our data: • Consistency check on L lifetime yields t(L)=267±5 ps [PDG: 263 ps]. CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  15. Comparison to world data STAR Preliminary • Lifetime related to binding energy • Theory input: the L is lightly bound in the hypertriton [1] R. H. Dalitz, Nuclear Interactions of the Hyperons (Oxford Uni. Press, London, 1965). [2] R.H. Dalitz and G. Rajasekharan, Phys. Letts. 1, 58 (1962). [3] H. Kamada, W. Glockle at al., Phys. Rev. C 57, 1595(1998). CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  16. STAR Preliminary Measured invariant yields and ratios In a coalescence picture: 0.45 ~ (0.77)3 CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  17. uud 3LH uds 3He t udd Yields/ratios as a measure of correlation Wave function overlaping Coalescence Yield depends on the correlation in both coordinate and momentum space (3He, t, 3LH)(u, d, s)+4u+4d A simple and perfect system! • 3LH/3He ratio  Lambda-nucleon correlation • 3He/t ratio  charge-baryon correlation uud uud udu udd udd udd CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  18. Yields/ratios as a measure of correlation STAR Preliminary measurements related to local (strangeness, baryon) - baryon correlation Lattice Simulations of (all strangeness) - (all baryon) correlation at zero chemical potential CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  19. Search for onset of deconfinement (string melting) AMPT (default) S. Zhang et al., arXiv:0908.3357 [nucl-ex] Hypertriton only STAR: DAQ1000+TOF CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  20. The / ratio is measured as 0.49±0.18, and 3He / 3He is 0.45±0.02, favoring the coalescence picture. • The / 3He ratio is determined to be 0.89 ± 0.28, and Conclusions • has been observed for 1st time; significance ~4s. • Consistency check has been done on analysis; significance is ~5s • The lifetime is measured to be / 3He is 0.82 ± 0.16. No extra penalty factor observed for hypertritons at RHIC. Strangeness phase space equilibrium CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  21. Outlook Lifetime: • –data samples with larger statistics (~factor 10 more within a few years) Production rate: –baryon-strangeness correlation – a case for energy scan – establish trend from AGS-SPS-RHIC-LHC 3LHd+p+p channel measurement: d-identification via TOF. Search for other hypernucleus: 4LH, 4LHe, 4LLH,3XH, Search for anti-a RHIC: best antimatter machine ever built CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  22. Extend to the sector of strangeness and antimatter CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  23. Hypernucleus at CSR energy Song Zhang (SINAP), ART + Coalescence 100 in 100M Ca+Ca @ 1 GeV (~ Au+Au @ RHIC top energy) But in few seconds Basic detectors: Dipole, tracking, TOF and neutron wall CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  24. Hypernucleus at higher energy Smaller penalty factor, higher strangeness production rate A. Andronic, P. Braun-Munzinger, J. Stachel, Nucl. Phys. A 772 (2006) 167. P. Braun-Munzinger, J. Stachel, J. Phys. G 21 (1995) L17 A. Andronic: SQM09 CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  25. International Hyper-nuclear network • PANDA at FAIR • 2012~ • Anti-proton beam • Double -hypernuclei • -ray spectroscopy • SPHERE at JINR • Heavy ion beams • Single -hypernuclei CBM? • HypHI at GSI/FAIR • Heavy ion beams • Single -hypernuclei at • extreme isospins • Magnetic moments • MAMI C • 2007~ • Electro-production • Single -hypernuclei • -wavefunction CSR? • 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  • BNL • Heavy ion beams • Anti-hypernuclei • Single -hypernuclei • Double L-hypernuclei Basic map from Saito, HYP06 CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

  26. Thank my STAR Collaborators for providing the perfect detectors and exciting results! Acknowledgement CBM-China Meeting, Tsinghua U., Nov. 2-5, 2009

More Related