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Forefront Issues in Meson Spectroscopy

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1 Forefront Issues in Meson Spectroscopy
Curtis A. Meyer Carnegie Mellon University July 24, 2006 July 24, 2006 National Nuclear Physics Summer School

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Outline of Talk Introduction Meson Spectroscopy Glueballs Expectations Experimental Data Interpretation Hybrid Mesons Summary and Future July 24, 2006 National Nuclear Physics Summer School

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QCD is the theory of quarks and gluons white 3 Colors 3 Anti-colors 8 Gluons, each of which has a color an an anti-color Charge. u d s c b t Six Flavors of quarks July 24, 2006 National Nuclear Physics Summer School

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Jets at High Energy Direct evidence for gluons come from high energy jets. But this doesn’t tell us anything about the “static” properties of glue. We learn something about s 2-Jet 3-Jet gluon bremsstrahlung July 24, 2006 National Nuclear Physics Summer School

5 Deep Inelastic Scattering
As the nucleon is probed to smaller and smaller x, the gluons become more and more important. Much of the nucleon momentum and most of its spin is carried by gluons! Glue is important to hadronic structure. July 24, 2006 National Nuclear Physics Summer School

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Strong QCD See and systems. Color singlet objects observed in nature: white Nominally, glue is not needed to describe hadrons. Focus on “light-quark mesons” Allowed systems: , , July 24, 2006 National Nuclear Physics Summer School

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Normal Mesons Non-quark-antiquark quark-antiquark pairs orbital r3,w3,f3,K3 r2,w2,f2,K2 r1,w1,f1,K1 p2,h2,h’2,K2 L=2 3-- 2-- 1-- 2-+ u d s u d s radial a2,f2,f’2,K2 a1,f1,f’1,K1 a0,f0,f’0,K0 b1,h1,h’1,K1 L=1 2++ 1++ 0++ 1+- J=L+S P=(-1) L+1 C=(-1) L+S G=C (-1) I (2S+1) L J 1S0 = 0 -+ 3S1 = 1-- r,w,f,K* p,h,h’,K L=0 1-- 0-+ July 24, 2006 National Nuclear Physics Summer School

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Nonet Mixing The I=0 members of a nonet can mix: SU(3) physical states Ideal Mixing: July 24, 2006 National Nuclear Physics Summer School

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Spectrum 1.0 1.5 2.0 2.5 qq Mesons L = 0 1 2 3 4 Each box corresponds to 4 nonets (2 for L=0) exotic nonets 0 – + 0 + – 1 + + 1 + – 1– + 1 – – 2 – + 2 + – 2 + + 0 + + Glueballs Hybrids Radial excitations Lattice GeV GeV (L = qq angular momentum) July 24, 2006 National Nuclear Physics Summer School

10 Glueball Mass Spectrum
QCD is a theory of quarks and gluons What role do gluons play in the meson spectrum? Lattice calculations predict a spectrum of glueballs. The lightest 3 have JPC Quantum numbers of 0++ , 2++ and 0-+. The lightest is about 1.6 GeV/c2 f0(1710) f0(1500) a0(1450) K*0(1430) f0(1370) a0(980) Morningstar et al. f0(980) July 24, 2006 National Nuclear Physics Summer School

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Glue-rich channels Where should you look experimentally for Glueballs? G M Radiative J/ Decays 0-+ (1440) 0++ f0(1710) Large signals Proton-Antiproton Annihilation Central Production (double-pomeron exchange) July 24, 2006 National Nuclear Physics Summer School

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Decays of Glueballs? Glueballs should decay in a flavor-blind fashion. ’=0 is true for any SU(3) singlet and for any pseudoscalar mixing angle. Only an SU(3) “8” can couple to ’. Flavor-blind decays have always been cited as glueball signals. Not necessarily true – coupling proportional to daughter mass can distort this. July 24, 2006 National Nuclear Physics Summer School

13 Crystal Barrel Results
Crystal Barrel Results: antiproton-proton annihilation at rest Study decays of X Discovery of the f0(1500) f0(1500) a pp, hh, hh’, KK, 4p Solidified the f0(1370) f0(1370) a 4p Crystal Barrel Results Discovery of the a0(1450) Establishes the scalar nonet 250,000 hhp0 Events 700,000 p0p0p0 Events f2(1565)+s f0(1500) f2(1270) f0(980) f0(1500) July 24, 2006 National Nuclear Physics Summer School

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The f0(1500) Is it possible to describe the f0(1500) as a member of a meson nonet? Use SU(3) and OZI suppression to compute relative decays to pairs of pseudoscalar mesons Get an angle of about 143o 90% light-quark 10% strange-quark Both the f0(1370) and f0(1500) are July 24, 2006 National Nuclear Physics Summer School

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WA102 Results CERN experiment colliding p on a hydrogen target. Central Production Experiment Recent comprehensive data set and a coupled channel analysis. July 24, 2006 National Nuclear Physics Summer School

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BES Results Clear Production of f0(1500) and f0(1710), no report of the f0(1370). f0(1710) has strongest production. July 24, 2006 National Nuclear Physics Summer School

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Model for Mixing meson 1 meson Glueball r2 Glueball meson r3 flavor blind? r Solve for mixing scheme F.Close: hep-ph/ July 24, 2006 National Nuclear Physics Summer School

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Meson Glueball Mixing Physical Masses f0(1370),f0(1500),f0(1710) Bare Masses: m1,m2,mG (G) (S) (N) f0(1370)   0.07 f0(1500)  0.04 –0.700.07 f0(1710)   0.02 ~(|1>-|G>) ~(|8>-|G>) ~(|1>+|G>) m1=137720 m2=167410 mG=144324 Lattice of about 1600 July 24, 2006 National Nuclear Physics Summer School

19 Glueball Expectations
Antiproton-proton: Couples to Observe: f0(1370),f0(1500) Central Production: Couples to G and in phase. Observe: f0(1370),f0(1500), weaker f0(1710). Radiative J/: Couples to G, |1>, suppressed |8> Observe strong f0(1710) from constructive |1>+G Observe f0(1500) from G Observe weak f0(1370) from destructive |1>+G Two photon: Couples to the quark content of states, not to the glueball. Not clear to me that has been seen. July 24, 2006 National Nuclear Physics Summer School

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Higher mass glueballs? Lattice predicts that the 2++ and the 0-+ are the next two, with masses just above 2GeV/c2. Radial Excitations of the 2++ ground state L= States + Radial excitations f2(1950), f2(2010), f2(2300), f2(2340)… 2’nd Radial Excitations of the  and ’, perhaps a bit cleaner environment! (I would Not count on it though….) I expect this to be very challenging. Evidence from BES for an (1760)! . July 24, 2006 National Nuclear Physics Summer School

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Lattice QCD Flux Tubes Realized From G. Bali Color Field: Because of self interaction, confining flux tubes form between static color charges Confinement arises from flux tubes and their excitation leads to a new spectrum of mesons July 24, 2006 National Nuclear Physics Summer School

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Flux Tubes July 24, 2006 National Nuclear Physics Summer School

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Hybrid Mesons built on quark-model mesons excited flux-tube m=1 ground-state flux-tube m=0 1-+ or 1+- normal mesons S=0,L=0,m=1 J=1 CP=+ JPC=1++,1-- (not exotic) S=1,L=0,m=1 J=1 CP=- CP={(-1)L+S}{(-1)L+1} ={(-1)S+1} JPC=0-+,0+- 1-+,1+- 2-+,2+- exotic m=0 CP=(-1) S+1 m=1 CP=(-1) S Flux-tube Model July 24, 2006 National Nuclear Physics Summer School

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QCD Potential linear potential ground-state flux-tube m=0 excited flux-tube m=1 Gluonic Excitations provide an experimental measurement of the excited QCD potential. Observations of exotic quantum number nonets are the best experimental signal of gluonic excitations. July 24, 2006 National Nuclear Physics Summer School

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Hybrid Predictions Flux-tube model: 8 degenerate nonets 1++, ,0+-,1-+,1+-,2-+,2+- ~1.9 GeV/c2 S=0 S=1 Lattice calculations nonet is the lightest UKQCD (97) 0.20 MILC (97) 0.30 MILC (99) 0.10 Lacock(99) 0.20 Mei(02) 0.10 Bernard(04) §0.139 § 0.2 § 0.11 § 0.6 In the charmonium sector: 0.08 0.11 Splitting = 0.20 July 24, 2006 National Nuclear Physics Summer School

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Decays of Hybrids Decay calculations are model dependent, but the 3P0 model does a good job of describing normal meson decays. 0++ quantum numbers (3P0) The angular momentum in the flux tube stays in one of the daughter mesons (L=1) and (L=0) meson. L=0: ,,,,… L=1: a,b,h,f,… ,, … not preferred. 1b1,f1,,a ,21,11,9 MeV (partial widths) first lattice prediction ~400MeV July 24, 2006 National Nuclear Physics Summer School

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E852 Results p-p -> hp- p (18 GeV) Mass = MeV/c2 Width= MeV/c2 p1(1400) The a2(1320) is the dominant signal. There is a small (few %) exotic wave. a2 p1 Interference effects show a resonant structure in 1-+ . (Assumption of flat background phase as shown as 3.) July 24, 2006 National Nuclear Physics Summer School

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CBAR Exotic Crystal Barrel Results: antiproton-neutron annihilation Mass = MeV/c2 Width= MeV/c2 Same strength as the a2. p1(1400) Produced from states with one unit of angular momentum. Without p1 c2/ndf = 3, with = 1.29 hp0p- July 24, 2006 National Nuclear Physics Summer School

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Controversy In analysis of E852 ± data, so evidence of the 1(1400) In CBAR data, the 0 channel is not conclusive. Analysis by Szczepaniak shows that the exotic wave is not resonant – a rescattering effect. The signal is far too light to be a hybrid by any model. This is not a hybrid and may well not be a state. July 24, 2006 National Nuclear Physics Summer School

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E852 Results At 18 GeV/c to partial wave analysis suggests July 24, 2006 National Nuclear Physics Summer School

31 understood acceptance
An Exotic Signal Correlation of Phase & Intensity Exotic Signal p1(1600) Leakage From Non-exotic Wave due to imperfectly understood acceptance 3p m= G= ph’ m= G= July 24, 2006 National Nuclear Physics Summer School

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In Other Channels E852 Results 1-+ in ’ p-p  ’-p at 18 GeV/c The 1(1600) is the Dominant signal in ’. Mass = 1.597 GeV Width = 0.3400.040 GeV 1(1600)  ’ July 24, 2006 National Nuclear Physics Summer School

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In Other Channels E852 Results 1-+ in f1 and b1 p-p  +--p p-p  w0-p 1(1600)  b1 1(1600)  f1 Mass=1.709 GeV Width=0.4030.08 GeV In both b1 and f1, observe Excess intensity at about 2GeV/c2. Mass ~ 2.00 GeV, Width ~ 0.2 to 0.3 GeV Mass = 1.687 GeV Width = 0.2060.03 GeV July 24, 2006 National Nuclear Physics Summer School

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1(1600) Consistency 3 m= =168 0 m= =340 f1 m= =403 b1 m= =206 Not Outrageous, but not great agreement. Mass is slightly low, but not crazy. Szczepaniak: Explains much of the 0 signal as a background rescattering similar to the . Still room for a narrower exotic state. July 24, 2006 National Nuclear Physics Summer School

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New Analysis Dzierba et. al. PRD 73 (2006) Add 2(1670)! (L=3) Add 2(1670)!3 Add 2(1670)! ()S Add a3 decays Add a4(2040) 10 times statistics in each of two channels. Get a better description of the data via moments comparison No Evidence for the 1(1670) July 24, 2006 National Nuclear Physics Summer School

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p1 IG(JPC)=1-(1-+) h’1 IG(JPC)=0+(1-+) h1 IG(JPC)=0+(1-+) K1 IG(JPC)= ½ (1-) Exotic Signals 1(1400) Width ~ 0.3 GeV, Decays: only  weak signal in p production (scattering??) strong signal in antiproton-deuterium. NOT A HYBRID Does this exist? 1(1600) Width ~ 0.16 GeV, Decays ,’,(b1) Only seen in p production, (E852 + VES) 1(2000) Weak evidence in preferred hybrid modes f1 and b1 The right place. Needs confirmation. July 24, 2006 National Nuclear Physics Summer School

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Exotics and QCD In order to establish the existence of gluonic excitations, We need to establish the existence and nonet nature of the 1-+ state. We need to establish at other exotic QN nonets – the 0+- and 2+-. In the scalar glueball sector, the decay patterns have provided the most sensitive information. I expect the same will be true in the hybrid sector as well. DECAY PATTERS ARE CRUCIAL July 24, 2006 National Nuclear Physics Summer School

38 Photoproduction More likely to find exotic hybrid mesons using beams of photons July 24, 2006 National Nuclear Physics Summer School

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The GlueX Experiment July 24, 2006 National Nuclear Physics Summer School

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Exotics in Photoproduction 1-+ nonet p1 IG(JPC)=1-(1-+) h’1 IG(JPC)=0+(1-+) h1 IG(JPC)=0+(1-+) K1 IG(JPC)= ½ (1-) N g e X g  ,, Need to establish nonet nature of exotics:   0 Need to establish more than one nonet: July 24, 2006 National Nuclear Physics Summer School

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0+- and 2+- Exotics N g e X In photoproduction, couple to r, w or f? b0 IG(JPC)=1+(0+-) h0 IG(JPC)=0-(0+-) h’0 IG(JPC)=0-(0+-) K0 I(JP)=½(0+) a1,f0,f1 wf0,wf1,ra1 ff0,ff1,ra1 wp, a1,f0,f1 b2 IG(JPC)=1+(2+-) h2 IG(JPC)=0-(2+-) h’2 IG(JPC)=0-(2+-) K2 I(JP)= ½(2+) “Similar to p1 ” wh,rp,wf0,wf1,ra1 fh,rp,ff0,ff1,ra1 Kaons do not have exotic QN’s July 24, 2006 National Nuclear Physics Summer School

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Summary The first round of J/ experiments opened the door to exotic spectroscopy, but the results were confused. LEAR at CERN opened the door to precision, high-statistics spectroscopy experiments and significantly improved both our understanding of the scalar mesons and the scalar glueball. Pion production experiments at BNL (E852) and VES opened the door to states with non-quark-anti-quark quantum numbers. Recent analysis adds to controversy. CERN central production (WA102) provided solid new data on the scalar sector, and a deeper insight into the scalar glueball. BES is collecting new J/ data. CLEO-c can hopefully add with the 0 program. July 24, 2006 National Nuclear Physics Summer School

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The Future The GlueX experiment at JLab will be able to do for hybrids what Crystal Barrel and WA102 (together) did for glueballs. What are the properties of static glue in light-quark hadrons and how is this connected to confinement. The antiproton facility at GSI (HESR) will look for hybrids in the charmonium system – PANDA. May also be able to shed more light on the Glueball spectrum. July 24, 2006 National Nuclear Physics Summer School


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