Presentation is loading. Please wait.

Presentation is loading. Please wait.

The role of anomalous triangle singularity in the understanding of threshold phenomena XVI International Conference on Hadron Spectroscopy September 13-18,

Published byShanon Lewis Modified over 8 years ago

Similar presentations

Presentation on theme: "The role of anomalous triangle singularity in the understanding of threshold phenomena XVI International Conference on Hadron Spectroscopy September 13-18,"— Presentation transcript:

1 The role of anomalous triangle singularity in the understanding of threshold phenomena XVI International Conference on Hadron Spectroscopy September 13-18, 2015, Newport News Institute of High Energy Physics Qiang Zhao Institute of High Energy Physics, CAS and Theoretical Physics Center for Science Facilities (TPCSF), CAS zhaoq@ihep.ac.cn

2 Outline 1. Motivation: kinematic effects or genuine states? 2. Anomalous triangle singularity 3. Cases to recognize anomalous triangle singularity: Heavy pentaquark production at LHCb 4. Summary

3 1. Motivation: kinematic effects or genuine states?

4 Multi-faces of QCD: Exotic hadrons Hybrid Glueball Tetraquark Pentaquark Hadronic molecule Evidence for QCD exotic states is a missing piece of knowledge about the Nature of strong QCD. u u d d u d d d d u  Proton Neutron Deuteron: p-n molecule

5 New quarkonium-like states, i.e. X, Y, Z’s, are observed in experiment Do not fit in the conventional quarkonium spectrum as quark-antiquark states, e.g. X(3872), Y(4260), X(3900) etc. Most of these new states, such as X(3872), are located close to a two-particle threshold. Evidence for charged quarkonium states, e.g. Zb(10610), Zb(10650), Zc(3900), Zc(4020), Z(4430), etc. In some cases, isospin or heavy quark symm. are violated. Good candidates for hadronic molecules or other non- standard configurations, e.g. tetraquarks, hybrids, etc. Brief summary of the exp. progress Evidence for heavy pentaquarks, i.e. Pc(4380) and Pc(4430), reported by LHCb.

6 2. Anomalous triangle singularity

7 7 Anomalous triangle singularity The ATS occurs when all the three internal particles can be simultaneously on shell. It corresponds to for all j=1,2,3. L. D. Landau, Nucl. Phys. 13, 181 (1959). G. Bonnevay, I. J. R. Aitchison and J. S. Dowker, Nuovo Cim. 21, 3569 (1961).

8 8 Kinematics : The ATS condition for fixed s 1, m j, and s 3 is: Or for fixed s 1, m j, and s 2 : X.-H. Liu and Q. Zhao, arXiv:1507.01674 [hep-ph]

9 9 Single dispersion relation in s 2 : The spectral function σ(s 1, s 2, s 3 ) can be obtained by means of the Cutkosky’s rules (absorptive part of the loop amplitude) or the formula which reads

10 10 For fixed s 1, s 3 and m i, the spectral function σ(s 1, s 2, s 3 ) has logarithmic branch points s ± 2, which correspond to the anomalous thresholds by solving the Landau equation. How the logarithmic branch points s ± 2 move as s 1 increases from the threshold of (m 2 + m 3 ) 2, with s 3 and m i fixed? Substituting s 1 →s 1 +i , s ± 2 in the s′-plane are then located at The normal thresholds and critical values for s 1 and s 2 as follows, With

11 11 Trajectory of s ± 2 in the complex s′ 2 -plane with s 1 increasing from s 1N to . P:

12 12 The difference between the normal and anomalous thresholds: When s 2 =s 2N (s 1 =s 1N ), we will obtain the maximum value of  s 1 (  s 2 ),

13 3. Cases to recognize anomalous triangle singularity: Heavy pentaquark production at LHCb Many other cases: J.-J. Wu, X.-H. Liu, and Q. Zhao, B.-S. Zou, PRL108, 081003 (2012) X.-G. Wu, J.-J. Wu, Q. Zhao, B.-S. Zou, PRD 87, 014023 (2013) Q. Wang, C. Hanhart, Q. Zhao, PRL111, 132003 (2013) Q. Wang, C. Hanhart, Q. Zhao, PLB725, 106 (2013) X.-H. Liu, Q. Zhao, arXiv:1507.01674 [hep-ph] A. P. Szczepaniak, PLB747, 410 (2015) [arXiv:1501.01691 [hep-ph]] M.Mikhasenko, B. Ketzer and A. Sarantsev, PRD 094015 (2015) [arXiv:1501.07023 [hep-ph]]

14 14 Pc  (4380) Pc  (4450) arXiv:1507.03414v2 [hep-ex], PRL(2015)

15 15 Data analysis including  * and pentaquark states M[Pc  (4380)] = (4380  8  29) MeV,  = (205  18  86) MeV M[Pc  (4450)] = (4449.8  1.7  2.5) MeV,  =(39  5  19) MeV J P = (3/2 , 5/2  ) or (3/2 , 5/2  )

16 16 Immediate theoretical studies: 1) Molecular states: R. Chen, X. Liu, X.-Q. Li, S.-L. Zhu, arXiv:1507.03704[hep-ph] L. Roca, J. Nieves and E. Oset, arXiv:1507.04249 [hep-ph]. A. Feijoo, V. K. Magas, A. Ramos and E. Oset, arXiv:1507.04640 [hep-ph] J. He, arXiv:1507.05200 [hep-ph] U.-G. Meissner, J.A. Oller, arXiv:1507.07478v1 [hep-ph] 2) Multiquark state as an overall color singlet L. Maiani, A.D. Polosa, and V. Riquer, arXiv:1507.04980 [hep-ph] R.L. Lebed, arXiv:1507.05867 [hep-ph] V.V. Anisovich et al., arXiv:1507.07652[hep-ph] G.-N. Li, X.-G. He, M. He, arXiv:1507.08252 [hep-ph] 3) Soliton model N.N. Scoccolaa, D.O. Riska, Mannque Rho, arXiv:1508.01172 [hep-ph] 4) Sum rules study H. X. Chen, W. Chen, X. Liu, T.G. Steele and S. L. Zhu, arXiv:1507.03717 Z.-G. Wang, arXiv:1508.01468.

17 17 Alternative solutions? Or some further concerns? Threshold enhancement produced by anomalous triangle singularity: F.-K. Guo, U.-G. Meissner, W. Wang, and Z. Yang, arXiv:1507.04950 [hep-ph] X.-H. Liu, Q. Wang, and Q. Zhao, arXiv:1507.05359 [hep-ph] M. Mikhasenko, arXiv:1507.06552v1 [hep-ph] Some early studies: J. J. Wu, R. Molina, E. Oset and B. S. Zou, Phys. Rev. Lett. 105, 232001 (2010) [arXiv:1007.0573 [nucl-th]]. J. J. Wu, R. Molina, E. Oset and B. S. Zou, Phys. Rev. C 84, 015202 (2011) [arXiv:1011.2399 [nucl-th]]. J. J. Wu, T.-S. H. Lee and B. S. Zou, Phys. Rev. C 85, 044002 (2012) [arXiv:1202.1036 [nucl-th]]. Z. C. Yang, Z. F. Sun, J. He, X. Liu and S. L. Zhu, Chin. Phys. C 36, 6 (2012) [arXiv:1105.2901 [hep-ph]].

18 18 Challenges for difference scenarios: 1) The narrow Pc(4450), if has JP=5/2+, would require a P-wave coupling between e.g.  c*(2520)  D*. A strong attractive force is required to bring the mass below threshold in a P wave. Then, how about the S wave? Similar questions for the lower one. 2) Why the lower one is much broader than the higher one? 3) How about other channels with  c*  D(*) and  c*  D(*) interactions? How many states we would expect and why only two states are seen? 4) Pentaquarks with hidden b  b ? 5) If the threshold interaction plays a role, how to distinguish the threshold kinematic effects from genuine states? ……

19 19 Production mechanism in  b decay Rescattering via triangle diagrams

20 20 Rescattering to generate a pole? A new leading order mechanism Favored by the molecular picture

21 21 The anomalous triangle singularity can be recognized F.-K. Guo, U.-G. Meissner, W. Wang, and Z. Yang, arXiv:1507.04950 [hep-ph] X.-H. Liu, Q. Wang, and Q. Zhao, arXiv:1507.05359 [hep-ph] M. Mikhasenko, arXiv:1507.06552v1 [hep-ph]

22 22 Thresholds for  cJ p X.-H. Liu, Q. Wang, and Q. Zhao, arXiv:1507.05359 [hep-ph]

23 23

24 24 Invariant mass distribution of J/  p with different K − p momentum cuts

25 25 F.-K. Guo, U.-G. Meissner, W. Wang, and Z. Yang, arXiv:1507.04950 [hep-ph] The ATS can mimic a resonance behavior in certain cases

26 26 How to distinguish an ATS enhancment from a genuine state? 1)If it is a genuine states, the signal in the invariant mass distribution of J/  p should be process independent. 2)The signal should still be present in a process where the ATS does not contribute, e.g. J/  photoproduction off nucleon. Q. Wang, X.-H. Liu, and Q. Zhao, PRD(2015); arXiv:1508.00339 [hep-ph] V. Kubarovsky and M.B. Voloshin, arXiv:1508.00888 [hep-ph] M. Karliner and J. Rosner, arXiv:1508.01496 [hep-ph] J. J. Wu and T.-S. H. Lee, arXiv:1212.2440 [nucl-th] Y. Huang, J. He, H. F. Zhang and X. R. Chen, J. Phys. G 41, 115004 (2014)

27 27 J/  photoproduction near threshold: Diffractive dominant at forward angle: Pomeron exchange model Q. Wang, X.-H. Liu, and Q. Zhao, PRD(2015); arXiv:1508.00339 [hep-ph]

28 0 180 d  /d  Scattering angle 1)Forward angle peaking is predominant due to the diffractive process, i.e. Pomeron exchanges. 2)S-channel resonance excitations contribute to the cross sections at middle and backward angles. 3)U-channel contributes to backward angles. t-channel: Pomeron exchange s-channel u-channel 90 Kinematic features of the production mechanism Interferences from different transition mechanisms

29 29 s and u-channel pentaquark production Coupling vertices for  NP c : S. H. Kim, S. i. Nam, Y. Oh and H. C. Kim, PRD 84, 114023 (2011) Q. Wang, X.-H. Liu, and Q. Zhao, arXiv:1508.00339 [hep-ph]

30 30 Coupling vertices for J/  NP c : Leading transition matrix elements: Rarita-Schwinger spin projections: with

31 31 e+e+ ee p PcPc J/   p p PcPc  p Vector meson dominance eh1eh1 g1g1 By assuming that the J/  p saturate the decay widths of the Pc states, we have A form factor is included:

32 32 Total cross sections predicted: Full width prediction Prediction with 5% of b.r. to J/  p:

33 33 Predicted differential cross sections at different energies: W= 4.15 GeVW= 4.38 GeV W= 4.45 GeVW= 4.50 GeV

34 34 W= 4.15 GeVW= 4.38 GeV W= 4.45 GeV W= 4.50 GeV Predicted differential cross sections at different energies:

35 4. Summary The anomalous triangle singularity is strongly correlated with threshold phenomena for which the physical consequences also need to be understood. Many cases seem to be indicating the ATS effects. The pentaquark candidates observed by LHCb may have filled a missing piece of the strong QCD jigsaw puzzle. However, there are still many things to be understood. The J/  photoproduction serves as an ideal process to distinguish the ATS enhancement from a genuine state which can be studied at JLab in the near future.

36 36 Thanks for your attention! Institute of High Energy Physics

Download ppt "The role of anomalous triangle singularity in the understanding of threshold phenomena XVI International Conference on Hadron Spectroscopy September 13-18,"

Similar presentations

Η photo-production off nucleons Some evidence of D 15 (2080) in the reaction Xian-Hui Zhong Hunan Normal University In collaboration with Qiang Zhao.

Η photo-production off nucleons Some evidence of D 15 (2080) in the reaction Xian-Hui Zhong Hunan Normal University In collaboration with Qiang Zhao.
1 Eta production Resonances, meson couplings Humberto Garcilazo, IPN Mexico Dan-Olof Riska, Helsinki … exotic hadronic matter?

1 Eta production Resonances, meson couplings Humberto Garcilazo, IPN Mexico Dan-Olof Riska, Helsinki … exotic hadronic matter?
1 Charged Z’s at Ruslan Chistov (ITEP, Moscow) Representing the Belle Collaboration Quarkonium Working Group Workshop (Nara, NWU, December 2-5/2008) ●

1 Charged Z’s at Ruslan Chistov (ITEP, Moscow) Representing the Belle Collaboration Quarkonium Working Group Workshop (Nara, NWU, December 2-5/2008) ●
Qiang Zhao Institute of High Energy Physics, CAS and Theoretical Physics Center for Science Facilities (TPCSF), CAS Effective Field Theories in Particle.

Qiang Zhao Institute of High Energy Physics, CAS and Theoretical Physics Center for Science Facilities (TPCSF), CAS Effective Field Theories in Particle.
Possible existence of neutral hyper-nucleus with strangeness -2 and its production SPN 2014, Changsha, Dec. 12-14, 2014 Institute of High Energy Physics.

Possible existence of neutral hyper-nucleus with strangeness -2 and its production SPN 2014, Changsha, Dec , 2014 Institute of High Energy Physics.
“Exotic” hadron-hadron S-wave Interaction Bing-song Zou IHEP, Beijing.

“Exotic” hadron-hadron S-wave Interaction Bing-song Zou IHEP, Beijing.
Excitation of the Roper Resonance in Single- and Double-Pion Production in NN collisions Roper‘s resonance Roper‘s resonance a resonance without seeing.

Excitation of the Roper Resonance in Single- and Double-Pion Production in NN collisions Roper‘s resonance Roper‘s resonance a resonance without seeing.
Coherent  -meson Photo-production from Deuterons Near Threshold Wen-Chen Chang Wen-Chen Chang for LEPS collaboration Institute of Physics, Academia Sinica,

Coherent  -meson Photo-production from Deuterons Near Threshold Wen-Chen Chang Wen-Chen Chang for LEPS collaboration Institute of Physics, Academia Sinica,
EXOTIC MESONS WITH HIDDEN BOTTOM NEAR THRESHOLDS D2 S. OHKODA (RCNP) IN COLLABORATION WITH Y. YAMAGUCHI (RCNP) S. YASUI (KEK) K. SUDOH (NISHOGAKUSHA) A.

EXOTIC MESONS WITH HIDDEN BOTTOM NEAR THRESHOLDS D2 S. OHKODA (RCNP) IN COLLABORATION WITH Y. YAMAGUCHI (RCNP) S. YASUI (KEK) K. SUDOH (NISHOGAKUSHA) A.
Run-Hui Li Yonsei University Mainly based on R.H. Li, C.D. Lu, and W. Wang, PRD83:034034.

Run-Hui Li Yonsei University Mainly based on R.H. Li, C.D. Lu, and W. Wang, PRD83:
1 The theoretical understanding of Y(4260) CONG-FENG QIAO Graduate School, Chinese Academy of Sciences 20-23 SEPT 2006, DESY.

1 The theoretical understanding of Y(4260) CONG-FENG QIAO Graduate School, Chinese Academy of Sciences SEPT 2006, DESY.
Workshop on LEPS/SPring-8 new beamline, 28~29 July 2005, RCNP, Japan  + photoproduction with vector K* (including other recent results) Seung-il Nam *1,2.

Workshop on LEPS/SPring-8 new beamline, 28~29 July 2005, RCNP, Japan  + photoproduction with vector K* (including other recent results) Seung-il Nam *1,2.
Mikhail Bashkanov Encounters with Di-Baryons from the ABC-effect to a Resonance in the Proton-Neutron System Wasa-at-COSY.

Mikhail Bashkanov Encounters with Di-Baryons from the ABC-effect to a Resonance in the Proton-Neutron System Wasa-at-COSY.
Kraków, June 9th, 2015 Exotic quarkonium-like states Andrzej Kupsc Positronium – quarkonia XYZ studies at BESIII Zc states: Zc 0± (3900), Zc 0± (4020)

Kraków, June 9th, 2015 Exotic quarkonium-like states Andrzej Kupsc Positronium – quarkonia XYZ studies at BESIII Zc states: Zc 0± (3900), Zc 0± (4020)
QCD exotics and production of threshold states Institute of High Energy Physics, CAS Sixth Asia-Pacific Conference on Few-Body Problems in Physics APFB.

QCD exotics and production of threshold states Institute of High Energy Physics, CAS Sixth Asia-Pacific Conference on Few-Body Problems in Physics APFB.
K*Λ(1116) Photoproduction and Nucleon resonances K*Λ(1116) Photoproduction and Nucleon resonances Sang-Ho Kim( 金相鎬 ) (NTG, Inha University, Korea) In collaboration.

K*Λ(1116) Photoproduction and Nucleon resonances K*Λ(1116) Photoproduction and Nucleon resonances Sang-Ho Kim( 金相鎬 ) (NTG, Inha University, Korea) In collaboration.
Molecular Charmonium. A new Spectroscopy? II Russian-Spanish Congress Particle and Nuclear Physics at all Scales and Cosmology F. Fernandez D.R. Entem,

Molecular Charmonium. A new Spectroscopy? II Russian-Spanish Congress Particle and Nuclear Physics at all Scales and Cosmology F. Fernandez D.R. Entem,
Hyun-Chul Kim Department of Physics Inha University In collaboration with H.Y. Ryu, A. Hosaka, A. Titov EFB 22, Sept. 10, meson photoproduction.

Hyun-Chul Kim Department of Physics Inha University In collaboration with H.Y. Ryu, A. Hosaka, A. Titov EFB 22, Sept. 10, meson photoproduction.
Dian-Yong Chen Institute of Modern Physics, CAS FHNP’15 Beijing Hadronic Loop Contributions to Heavy Quarkonium Decay

Dian-Yong Chen Institute of Modern Physics, CAS FHNP’15 Beijing Hadronic Loop Contributions to Heavy Quarkonium Decay
Non-ordinary light meson couplings and the 1/Nc expansion Departamento de Física Teórica II. Universidad Complutense de Madrid J.R. Peláez PRD90, 036003.

Non-ordinary light meson couplings and the 1/Nc expansion Departamento de Física Teórica II. Universidad Complutense de Madrid J.R. Peláez PRD90,

Similar presentations

Ads by Google