Qiang Zhao Institute of High Energy Physics, CAS

1. Institute of High Energy Physics, CAS Puzzles in charmonium decays Qiang Zhao Institute of High Energy Physics, CAS and Theoretical Physics Center for Science Facilities (TPCSF), CAS USCT, Hefei, July 9, 2009

2. Outline • Charmonium decays as a probe for non-perturbative QCD mechanisms • Several exisiting puzzles in charmonium decays

3. Several well-known puzzles in charmonium decays • “ puzzle” in J/,   VP decay • M1 transition problem in J/,    c, ( c) • (3770) non-DD decay • Isospin-violating decay of  J/ 0 • Hidden cc state with I=1, e.g. Z(4430), and other exotic configurations • Scalar a0(980)-f0(980) mixing in J/  f0(980)  0 • Glueball search in charmonium hadronic decays • “ puzzle” in J/,   VP decay • M1 transition problem in J/,    c, ( c) • (3770) non-DD decay • Isospin-violating decay of  J/ 0 • Hidden cc state with I=1, e.g. Z(4430), and other exotic configurations • Scalar a0(980)-f0(980) mixing in J/  f0(980)  0 • Glueball search in charmonium hadronic decays These puzzles could be related to non-pQCD mechanisms in charmonium decays.

4. Focus of hadron physics • Complexity of QCD in the non-perturbative regime exotic hadrons (glueball, hybrid, multiquarks …) • Lattice QCD, QCD sum rules, effective theory… Phenomenological tools • Break-down certain problems • Experimental information: Light hadron spectroscopy (JLab, ELSA, MAMI, ERSF, Spring-8); Heavy quarkonium hadronic and EM decays (BES, CLEO-c, Belle, BaBar, LHC…)

5. Charmonium spectrum

6. A probe of strong QCD dynamics q Meson c glue q J/ q qq Meson hybrid glueball c q • Glue-rich intermediate states • Ideal for the search for exotic states (hybrid, glueball …) • Quark-gluon interaction in light hadron production

7. A flavour filter for Okubo-Zweig-Iizuka (OZI) disconnected transitions = (uu + dd)/2  = ss V= (I=0) (I=0) c c J/ J/ uudd (I=0) qq (I=1) c c ss(I=0) • OZI rule violations • Isospin violations

8. Open-charm effects in charmonium decays ”(3770) DD threshold ’(3686) Mass (MeV) c(2980)  J/(3096) c(2980) OZI rule violating transition Light mesons , , K*K, … 0 (L=0,S=0) 1 (L=0,S=1) 1 (L=2,S=1)

9. DD  J/(3096) (3770) Mass axial (3686) The open DD threshold is close to (3686) and (3770), which suggests that these two states will experience or suffer the most from the open channel effects. However, such effects behave differently in the kinematics below or above the threshold.

10. (3770) non-DD decay -- Evidence for intermediate D meson contributions to charmonium decays

11. Particle Data Group 2008

12. Particle Data Group 2008

13. Particle Data Group 2008

14. (3770) non-DD decay • Experimental discrepancies: Exclsusive DD cross sections are measured at BES and CLEO-c:

15. BES-II: non-DD branching ratio can be up to 15% CLEO-c: The lower bound suggests the maximum of non-DD b.r. is about 6.8%.

16. Inclusive non-DD hadronic cross sections from BES

17. Theoretical discrepancies: In theory

18. pQCD calculation: BR(non-DD) < 5% • Short-range pQCD transition; • Color-octet contributions are small; • 2S-1D state mixings are small; • NLO correction is the same order of magnitude as LO. Q: How about the long-range non-pQCD mechanisms?

19. Recognition of long-range transition mechanisms • pQCD (non-relativistic QCD): • If the heavy cc are good constituent degrees of freedom, c and c annihilate at the origin of the (cc) wavefunction. Thus, pQCD should be dominant. • If pQCD is dominant in (3770)  light hadrons via 3g exchange, the OZI rule will be respected. •  (3770) non-DD decay will be suppressed. • Non-pQCD: • Are the constituent cc good degrees of freedom for (3770)  light hadrons? Or is pQCD dominant at all? • If not, how the OZI rule is violated? • Could the OZI-rule violation led to sizeable (3770) non-DD decay? • How to quantify it?

20. Recognition of long-range transition mechanisms in spectrum studies

21. Contact S*S from OGE; Implies S=0 and S=1 c.o.g. degenerate for L > 0. (Not true for vector confinement.) 1. Success of potential quark model OGE + Linear confinement; spin-dependent force is perturbative.

22. 2. Hadronic loop effects Unquench the naïve quark model scenario B A A C T. Barnes and E. Swanson, PRC77, 055206 (2008)

23. Three loop theorem For the states A in a given Ni and Li multiplet, “These hold to all orders if there are no final state interactions in the continuum channels.” Also by Tornqvist

24. Mass shift and cc-bar probabilities for low-lying charmonium states due to couplings to two-meson continua.

25. Recognition of long-range transition mechanisms in (3770) non-DD decays M1 g c M1  (3770) (3770) M2 c* M2

26. (3770) decays to vector and pseudoscalar via DD and DD* + c.c. rescatterings Zhang, Li and Zhao, Phys. Rev. Lett. 102, 172001 (2009)

27. The V  VP transition has only one single form of coupling as anti-symmetric tensor Transition amplitude can thus be decomposed as: Long-range non-pQCD amp. Short-range pQCD amp.

28. Effective Lagrangians for meson couplings Coupling constants:

29. i) Determine long-range parameter in (3770)  J/ . (3770) J/ (3770) J/   • Soft  production • - mixing is considered • a form factor is needed to kill the loop integral divergence The cut-off energy for the divergent meson loop integral can be determined by data, and then extended to other processes.

30. ii) Determine short-range parameter combing (3770)   and (3770)  . Relative strengths among pQCD transition amplitudes:

31. iii) Predictions for (3770)  VP.

32. Brief Summary -I • The t-channel transition is much more important than the s channel. • The s-channel can be compared with Rosner’s (2S)-(1D) mixing. • The only sizeable s channel is in (3770)  J/. It adds to the t-channel amplitude constructive. In contrast, the isospin-violating (3770)  J/0 experiences a destructive interference between the s and t channel. • There exists a strong correlation between the SOZI parameter gS and phase angle . By varying , but keeping the  rate unchanged (i.e., gS will be changed), we obtain a lower bound for the sum of branching ratios, 0.41%. • It is essential to have precise measurement of all the VP channels, i.e. , K*K+c.c. etc.

33. Brief Summary -II • Coherent study of the (3686)  VP is important for clarifying the role played by long-range transition mechanisms, in particular, the open-charm effects. • It is essential to quantify (3770)  VT, VS, etc. • It is important to investigate the meson loop effects in other processes, e.g. “ puzzle”, J/ and (3686) radiative decay. [see e.g. Zhao, Li and Chang, PLB645, 173(2007); Li, Zhao, and Chang, JPG (2008); Zhao, Li and Chang, arXiv:0812.4092[hep-ph], and work in progress] • It is important to investigate the relevant isospin-violating channels as a correlation with the OZI-rule violation (OZI-rule evading) process. [Wu, Zhao and Zou, PRD75, 114012(2007)] • An analogue to the (3770) non-DD decay: the (1020) non-KK decay [see Li, Zhao and Zou, PRD77, 014010(2008); Li, Zhang and Zhao, JPG in press]. • ……

34. “ puzzle” and “12% rule”

35. “ puzzle” and “12% rule” • pQCD expectation of the ratio between J/ and ' annihilation: • “ puzzle” R() =  0.2 % Large “12% rule” violation in  ! g c c * JPC = 1 J/, ' J/, ' c* c*

36. Theoretical explanations: • 1. J/   is enhanced • J/-glueball mixing: • Freund and Nambu, Hou and Soni, Brodsky, Lepage and Tuan • Final state interaction: • Li, Bugg and Zou • Intrinsic charmonium component within light vectors: • Brodsky and Karliner, Feldman and Kroll • 2. '   is suppressed • Karl and Roberts: sequential fragmentation model • Pinsky: hindered M1 transition model • Chaichian and Tornqvist: exponential form factor model • Chen and Braaten: color octet Fock state dominance in J/ • Rosner: ' and " mixing • 3. Others … Recent review by Yuan et al.

37. Branching ratios for J/ (cc)  V P Same order of magnitude ! • What accounts for such a large isospin violation? • Implications of the “ puzzle” …

38. Branching ratios for  V P Particle Data Group Comparable !?

39. +/ EM + Long-range int. 3g   +/ EM + Long-range int. 3g • “12% rule” will not hold if EM, and/or other possible transitions are important. V V g c c * J/ J/ P P c* c*

40. The property of antisymmetric VVP coupling suggests that one can investigate the origin of the “ puzzle” between the strong and EM transitions. • The EM transition can be investigated by vector meson dominance (VMD) model. • The strong transition amplitude contributes to both isospin-conserved and isospin-violated transitions.

41. EM transitions in VMD VP coupling: V* coupling: Transition amplitude:

42. I. Determine gVP in V   P  V P

43. II. Determine e/fV in V  e+ e- e+ * V e-

44. III. Determine gP in P    P  IV. Form factors Corrections to the V*P vertices: All the relevant data are available !

45. V. Isospin-violated channel We determine the cut-off energy  in the form factor by fitting the experimental branching ratios for the isospin-violating J/ and  decays. By taking the branching ratio fractions, it shows that the 12% rule is approximately satisfied. Rth(%) Rexp(%) • Note: • The short-distant 3g transition is suppressed. •  parameter is determined by assuming the dominance of EM transition in isospin-violated channels. It should be refitted when strong isospin violation is included.

46. Parameterize the strong decay transition • Fig. (a): Contributions from short-range interactions • Fig. (b): Contributions from long-range interactions with the double OZI-rule violation • Possible glueball components inside I=0 mesons Short-range dominant, single OZI process Long-range dominant, double OZI process

47. Parameterized strong decay amplitudes: reflects the strong decay coupling strength. Form factor to take into account hadron size effects: with

48. Fitting results Zhao, Li and Chang, PLB645, 173(2007) Li, Zhao, and Chang, JPG (2008)

49. Branching ratio fraction “R” including EM and strong transitions Zhao, Li and Chang, PLB645, 173(2007), Li, Zhao, and Chang, JPG (2008)

50. Unanswered questions • What is the origin of the strong coupling suppression on the   VP? • What is the role played by long-range interactions? • What is the correlation between the long-range interaction with the OZI-rule-evading mechanisms? Mechanisms suppressing the   VP strong decays should be clarified!