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Premium member Presentation Transcript Slide1: The meson landscape Scalars and Glue in Strong QCD New states beyond Weird baryons: pentaquark problems Frank Close ICHEP04 “Diquarks,Tetraquarks, Pentaquarks and no quarks” 1Slide2: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 9460 10023 9860 9893 9913 3686 3097 3415 3510 3556 3772 (cc*) Slide3: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 9460 10023 9860 9893 9913 3686 3097 3415 3510 3556 3772 (cc*) Radiative E1 transitions precision beyond simple cc* Hadronic decays entrée to gluonic light hadrons 1++ to pi and exotic 1-+ (hybrid) BES;CLEOc Glue-gamma interference -90 degrees(Wang) And 2S-1D mixing (Rosner) Solution to suppressed hadronic modes BES; CLEOcSlide4: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 (nn* ss*)Slide5: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 (nn* ss*) qq* seed dominates If no S-wave meson channels are open. S-wave hadrons hide qq* Production channels give different impressions of Fock state Big problem for scalars which couple to pi pi etc in s-wave even though qq* is in p-waveSlide6: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 1370/1500/1710/1790 6Slide7: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 980/600 1370/1500/1710/1790 7Slide8: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 0+ 1370/1500/1710/1790 980/600 ? qq* + Glueball Lattice G =1.6 \pm 8Scalar Glueball and Mixing: Scalar Glueball and Mixing s n G 9Scalar Glueball and Mixing a simple example for expt to rule out: Scalar Glueball and Mixing a simple example for expt to rule out Meson 1710 1500 1370 s n G 10Scalar Glueball and Mixing a simple example for expt to rule out: Meson G ss* nn* 1710 0.39 0.91 0.15 1500 - 0.65 0.33 - 0.70 1370 - 0.69 0.15 0.70 s n 0- 0- meson decays LEAR/ WA102 Scalar Glueball and Mixing a simple example for expt to rule out 11Slide12: Coming soon from BES and CLEO-c A flavour filter for 0++ 0-+ 2++ (and 1++) mesons glueballs et al >1 billion 1000 per meson Challenge: Turn Lattice QCD Glueball spectrum into physics 12Slide13: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 0+ 1370/1500/1710/1790 980/600 ? qq* + Glueball [qq][q*q*] seed and/or S-wave mesons 13Production chooses easiest route: interpretation needs care: Production chooses easiest route: interpretation needs care 980 (uu*+dd*)ss* 980 (uu*- dd*)ss* KLOE phi K K gamma S wave KK into 0++ long range wavefunction Says little about short range QCD wavefunction e.g. Contrast Xi_c(3400) \to f0(980)f0(980) (BES) and Z decays which feed f0(980) via “easiest” qq* like other hadronsNew states outside the quark model: cc* X(3872) anomalous charmonium: New states outside the quark model: cc* X(3872) anomalous charmonium 15Slide16: A new narrow charmonium state B decay = a new source of charmonium Charmonium candidates 2- 3- radial1+ are narrow below DD* Mass, width, angular dist etc all inconsistent with cc* Standard cc* theory wrong? Or is X(3872) not simple cc*? 16Slide17: DD* molecule “tetraquark” Mass same as neutral threshold to better than 1 in 10,000 cuc*u* S-wave JPC = 1++ = isospin maximally broken Close+Page Tornqvist Swanson Test: X \to K+K-\pi>> K0K0\pi CLEOc/BES test for 1++ 3550 also Rho? Also psi omega: BelleSlide18: cc*1++ 3550; 1++* 3950: DD* (neutral) threshold Psi rho; psi omega S-wave 1++ mesons P-wave cc* D D* psi uu* vector D D* D* D pi Energy degeneracy will drive this >> model details. Psi rho:psi omega \sim 1 Deviations = dynamics Specific model: Swanson Decays driven by meson-meson wavefunction Production by cc* residue: like psiprime S-wave meson-meson beats P-wave qq* (continued) 18 Mass coincidence only happens with Charm, not strange or bottomX(3872) summary: X(3872) summary cc* 1++ seed Meson-meson S-wave dominant 19Slide20: K Lambda eta N S-wave baryon-meson beats P-wave qqq Baryon S_{11} is qqq p-wave but prefers N-eta Rescatters to K Lambda (e.g. BES, previous talk) A Baryon analogue from BES ? (Shan Jin talk) 20 Psi to gamma p pbar enhancement/bound state also?New states outside the quark model: cs* (2317;2460;2635) : New states outside the quark model: cs* (2317;2460;2635) 22Novel states in : Novel states in 0+ 2317 1+ 2460 J^P=?… 2632 ultralite cs*; DK molecule Isospin violation as below DK threshold cs* 1- radial (nodes); mix with ^3D_1 = X cs*uu* (Iso violation); = X = artefact ? Narrow. Anomalous decays “anti” phase space 23Slide24: (also M.Nowak et al, HADRON2003) Why in cs*? Which 1+? 2560 1+ 243MeV 25Slide25: DK D*K 26Slide26: Whatever makes scalar f_0(980) light (= just below KK) (compared to qq* p-wave) Probably makes scalar 2317 light (= just below DK) (compared to qq* p-wave) …and 2460 axial light (just below D*K) Production by easiest route: cs* residue Decays driven by di-meson DK D*K TEST: 1+ \to 0+ \gamma (M1) D*K \to DK \gamma = D* \to D \gamma S-wave meson-meson beats P-wave qq* (continued) 27Another novel state in : Another novel state in J^P=? 2632 Narrow. Anomalous decays “anti” phase space 28Novel states in : Novel states in J^P=0+,1-… 2632 cs* 1- radial (nodes); mix with ^3D_1 cs*uu* (Iso violation); cqs*q* + css*s*(tetraquark in 15_f) Narrow. Anomalous decays “anti” phase space 29Novel states in : Novel states in J^P=0+,1-… 2632 cs* 1- radial (nodes); mix with ^3D_1 doesn’t work cs*uu* (Iso violation); D_s + pi^o D_s + gamma gamma = NO cqs*q* + css*s*(tetraquark in 15_f) 6_f more attractive; D_s gamma gamma = NO Narrow. Anomalous decays “anti” phase space 30Slide30: 2632 would be here 31D_{sJ} summary: D_{sJ} summary 2317/2460: cs* 0+ 1+ seeds Meson-meson S-wave DK D*K Dynamics like 0++(980) 2632: artefact 32Some Reflections on Pentaquarks: Some Reflections on Pentaquarks 33Slide33: ½+ Strangeness +1 baryon mass 1540MeV narrow width Predicted!!! DPP In chiral soliton model with unusual assumptions Narrow width an enigma Mass a problem Production mechanism unknown n.b. expt has not established ½+ It might not exist! 34Slide34: u d u d Q* u d Jaffe Wilczek ud udQ* Karliner Lipkin L=1 L=1 Diquark attractions for unlike flavours = basis for pentaquark models (has not been demonstrated how low mass scalar diquarks form, stability, effective bosons, consistency with other hadron spectroscopy… etc. = ?) Pentaquarks (if they exist) = strong QCD correlations Slide35: Arndt Buccella Carlson Dyakanov Ellis Faber Giannini Huang Inoue Jaffe Karliner Lipkin Maltman Nussinov Oh Polyakov Qiang Rosner Stech Trilling U Veneziano Wilczek Xiang Yang Zhu If Theta doesn’t exist, then these (and many other theorists) should be congratulated on their creativityMass: Mass 37Slide37: + Baryon DPP original M=(1890-180Y)MeV and revised Linear only for 10*. Mixing with 8 complicates. Mass formulae beware |S| versus S. Strange quark costs too much No simple map onto pentaquarkSlide38: (LEPS) Anomalies with Theta Mass? F. Close and Q. Zhao, hep-ph/0404075 39Slide39: Mass Fitted. Not calculated Dyakanov Petrov Polyakov DPP assumed N(1710) in 10bar Jaffe Wilzcek JW assumed N(1440) as (ud)(ud)dbar X mass formula bizarre: q_5 10bar mass gap 1/3 m_s X pure 10bar not photoproduced from p X width 300MeV X gamma n:gamma p = radial 56plet qqq X Delta(1670) partner Karliner Lipkin KL assume cs* 200MeV orbital to set scale X spin averaged cs* costs 500MeV, Theta= 1800MeVSlide40: u d u d Q* u d Jaffe Wilczek ud udQ* Karliner Lipkin Q* \to (ud) = anomalous deuteron (ud) \to Q* 10bar mesons P-wave 1-+ etc? e.g.Chung Klempt Widths? FC Dudek Burns Forces ud very light and L large What mechanism? What if……..? 41Width: Width 42Slide42: Chiral Soliton Theta-N-K Coupling involves three unknowns A; B; C B F/D Set scale with g(10*) = 1-B-C NRCQM: F/D=2/3 B=1/5 C= 4/5 g(10*)=0 g(10*) C After Ellis Karliner Prasalowicz Width Slide43: Width < 10 MeV direct experiments <1MeV Cahn Trilling; Nussinov;… 3/2- Lambda(1520) KN width 7 MeV Jaffe Wilzcek; Jennings Maltman; Carlson et al; Close Dudek;Buccella Stora Color flavor spin overlap suppression > 24 X D wave; P-wave Lambda1600 is 100 MeV X needs qq* creation whereas qqqqq* falls apart X color killed by soft gluon exchange X spin flip costs little X flavor killed by rearrangement Stech et al; Dudek; Carlson et al Spatial overlap suppression X no dynamical proof Stech ? Strong color-spin forces (Dudek) + Stech model….? 44Slide44: Width < 10 MeV experiments <1MeV Cahn Trilling; Nussinov;… Decouples from KN (small width) Strong coupling to something (strong production) How is Theta produced? ………………enigma 45Production: Production 46Slide46: Several experimental limits in hadron production Some not restrictive yet e.g. psi(3095) to Theta Thetabar (=3080) versus LambdaLambdabar (1/100) or can be “explained away” e.g. psiprime sees some channels reduced and this is another one; big price to produce 10 q and q* etc. My opinion (this week) Limits in high statistics look impressive. Onus is on supporters to explain them away or find a loophole ……….example of a possible loophole Lipkin Karliner next 47Slide47: Why seen in photons but not in high statistics hadrons? CLAS: Theta+K = N*(2.4GeV) (24ev/10bgnd) Suppose N*(uddss*) and gamma provides the ss* Problems CLAS see in gamma pi K Theta pi N N* No memory of gamma(ss*); should apply to hadrons too…..why not CDF? SPring8 and CLAS1 too low E(gamma) to make 2.4GeV N* 48The Mystery of the Sigma_5: The Mystery of the Sigma_5 The case of the dog that didn’t bark (Sherlock Holmes) If Theta is real, why isnt Sigma_5 (or Sigma* ½+ 1660) also seen? 49Slide49: Note pKs can be + or + Decays Dyakanov Petrov Polyakov; Close Dudek; Oh Kim Lee generalises 50Slide50: Gamma N \to K Theta Assuming s,t,u and contact diagramsSlide51: Gamma N \to K Sigma5 FC-Q Zhao Slide52: 0.5 53Absence of Sigma_5, or even Sigma(1660) in experiments that claim Theta is a worry.: M(pKs) HERMES Absence of Sigma_5, or even Sigma(1660) in experiments that claim Theta is a worry.Slide54: Dzierba Szczepaniak Teige Fake Peaks in gamma N N gamma N a2/rho3 55Slide55: Dzierba Szczepaniak Teige Fake Peaks in gamma N N a2/rho3 N K K D/F wave decay forward back to KKbar a2/rho3 gives charge asymmetry Same velocity NK mass 1440 “real” kinematics broadens hump….Slide56: Dzierba Szczepaniak Teige One is real (CLAS) Three are fake Can you tell which?Slide57: (LEPS) Could this also explain different nK+ and pKs masses? F. Close and Q. Zhao, hep-ph/0404075 Show Dalitz plots!! Different Q values for charged neutral feed into mass of fake Theta?Slide58: Paradoxes; Enigmas; Hints of unreality How is Theta produced? Why seen in low statistics photoproduction but not in high statistics hadroproduction? Decouples from KN (small width) Strong coupling to something (strong production) Why does mass vary? real (dynamic clue); statistics (non existence clue) Cascades (exotics) studied since BQM Beware! K-Theta+ why no K+Sigma- Ks Theta+ why no Ks Sigma+ Why is production Theta/Sigma(1660) = infinity? 59CONCLUSION: CONCLUSION Have Weird Multiquark Demons been found? Is there a 1 MeV wide, S=+1 baryon at 1540 MeV? If NO this is testament to the ingenuity of theorists whose models can explain it even if it doesn’t exist. Lattice QCD is almost unique in not having definitively disproved that such a state does not exist. 60CONCLUSION: CONCLUSION Precision and variety = Beyond qq* Strong Glue in QCD: Glueballs mix; psi to gam gam V opportunity. exotic hybrids emerging; Xi_{c1} decays opportunity Multiquarks/Molecules: X(3872) 1++ molecule (to be disproved) Ds(2317;2460) 0+ and 1+: cs* or DK/DK* (need to determine) Ds(2635) artefact (to be disproved) Pentaquarks/Theta: Artefact or Strong QCD very profound Opportunity for lattice to realise its investmentCONCLUSION: CONCLUSION YES No Keep searching Have Weird Multiquark Demons been found? Democratic voting paper/Florida counting principle Slide62: With thanks to the organisers, the scientific secretaries and the IHEP students who have made our time in Beijing so enjoyableThis slide sponsored by Oxford University Press: This slide sponsored by Oxford University Press A Very Short Introduction to Particle Physics A little red pocket book with no equations for physics undergraduates and your partners by Frank Close 10 dollars at amazon.com nowSlide65: Central Production pp \to pMp 0+ and 2+ qq* G ? Compare e+e- \to e+(qq*)e-Slide66: A new narrow charmonium state B decay = a new source of charmonium Standard cc* theory wrong? Or is X(3872) not simple cc*? Charmonium problemsSlide67: A conjecture: T.Barnes, F.E.Close, H.J.Lipkin, hep-ph/0305025, PRD. Reminiscent of Weinstein and Isgur’s KKbar molecules, bound by level repulsion of the KKbar continuum against higher mass qqbar 0+ scalars at ca. 1.3 GeV.Slide68: Mass Low “N”(940) + “K”(495) (L=1) = 115MeV (ud)+(uds*) < “N+K” (L=1) = 200MeV Karliner Lipkin 2.59 2.56 2.32 2.11 1.97 1- 0+ Ds(cs*) spectrum 210Slide69: Mass Low “N”(940) + “K”(495) (L=1) = 115MeV (ud)+(uds*) < “N+K” (L=1) = 200MeV Karliner Lipkin 400-480 1- 0+ 0- 1+ L=0 L=1 2+ 2.55 -2.47 2.07 Spin averaged masses in multiplet Theta = 1750-1830Slide70: Unique Isospin laboratory I=3/2 and I=1/2 but for narrow states flavour wins: =(dss)dd* =(dss)uu* 10MeVSlide71: (LEPS) MΘ F. Close and Q. Zhao, hep-ph/0404075 You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
p19 close f Silvestre Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 35 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: January 12, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Slide1: The meson landscape Scalars and Glue in Strong QCD New states beyond Weird baryons: pentaquark problems Frank Close ICHEP04 “Diquarks,Tetraquarks, Pentaquarks and no quarks” 1Slide2: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 9460 10023 9860 9893 9913 3686 3097 3415 3510 3556 3772 (cc*) Slide3: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 9460 10023 9860 9893 9913 3686 3097 3415 3510 3556 3772 (cc*) Radiative E1 transitions precision beyond simple cc* Hadronic decays entrée to gluonic light hadrons 1++ to pi and exotic 1-+ (hybrid) BES;CLEOc Glue-gamma interference -90 degrees(Wang) And 2S-1D mixing (Rosner) Solution to suppressed hadronic modes BES; CLEOcSlide4: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 (nn* ss*)Slide5: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 (nn* ss*) qq* seed dominates If no S-wave meson channels are open. S-wave hadrons hide qq* Production channels give different impressions of Fock state Big problem for scalars which couple to pi pi etc in s-wave even though qq* is in p-waveSlide6: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 1370/1500/1710/1790 6Slide7: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 980/600 1370/1500/1710/1790 7Slide8: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 0+ 1370/1500/1710/1790 980/600 ? qq* + Glueball Lattice G =1.6 \pm 8Scalar Glueball and Mixing: Scalar Glueball and Mixing s n G 9Scalar Glueball and Mixing a simple example for expt to rule out: Scalar Glueball and Mixing a simple example for expt to rule out Meson 1710 1500 1370 s n G 10Scalar Glueball and Mixing a simple example for expt to rule out: Meson G ss* nn* 1710 0.39 0.91 0.15 1500 - 0.65 0.33 - 0.70 1370 - 0.69 0.15 0.70 s n 0- 0- meson decays LEAR/ WA102 Scalar Glueball and Mixing a simple example for expt to rule out 11Slide12: Coming soon from BES and CLEO-c A flavour filter for 0++ 0-+ 2++ (and 1++) mesons glueballs et al >1 billion 1000 per meson Challenge: Turn Lattice QCD Glueball spectrum into physics 12Slide13: 2S: 1- 1S: 1- 1D: 1- 2+ 1+ 0+ 770 1460 1700 I=1 vector : I=0 JP = 2+ 1+ 0+ 1270/1525 1285/1530 0+ 1370/1500/1710/1790 980/600 ? qq* + Glueball [qq][q*q*] seed and/or S-wave mesons 13Production chooses easiest route: interpretation needs care: Production chooses easiest route: interpretation needs care 980 (uu*+dd*)ss* 980 (uu*- dd*)ss* KLOE phi K K gamma S wave KK into 0++ long range wavefunction Says little about short range QCD wavefunction e.g. Contrast Xi_c(3400) \to f0(980)f0(980) (BES) and Z decays which feed f0(980) via “easiest” qq* like other hadronsNew states outside the quark model: cc* X(3872) anomalous charmonium: New states outside the quark model: cc* X(3872) anomalous charmonium 15Slide16: A new narrow charmonium state B decay = a new source of charmonium Charmonium candidates 2- 3- radial1+ are narrow below DD* Mass, width, angular dist etc all inconsistent with cc* Standard cc* theory wrong? Or is X(3872) not simple cc*? 16Slide17: DD* molecule “tetraquark” Mass same as neutral threshold to better than 1 in 10,000 cuc*u* S-wave JPC = 1++ = isospin maximally broken Close+Page Tornqvist Swanson Test: X \to K+K-\pi>> K0K0\pi CLEOc/BES test for 1++ 3550 also Rho? Also psi omega: BelleSlide18: cc*1++ 3550; 1++* 3950: DD* (neutral) threshold Psi rho; psi omega S-wave 1++ mesons P-wave cc* D D* psi uu* vector D D* D* D pi Energy degeneracy will drive this >> model details. Psi rho:psi omega \sim 1 Deviations = dynamics Specific model: Swanson Decays driven by meson-meson wavefunction Production by cc* residue: like psiprime S-wave meson-meson beats P-wave qq* (continued) 18 Mass coincidence only happens with Charm, not strange or bottomX(3872) summary: X(3872) summary cc* 1++ seed Meson-meson S-wave dominant 19Slide20: K Lambda eta N S-wave baryon-meson beats P-wave qqq Baryon S_{11} is qqq p-wave but prefers N-eta Rescatters to K Lambda (e.g. BES, previous talk) A Baryon analogue from BES ? (Shan Jin talk) 20 Psi to gamma p pbar enhancement/bound state also?New states outside the quark model: cs* (2317;2460;2635) : New states outside the quark model: cs* (2317;2460;2635) 22Novel states in : Novel states in 0+ 2317 1+ 2460 J^P=?… 2632 ultralite cs*; DK molecule Isospin violation as below DK threshold cs* 1- radial (nodes); mix with ^3D_1 = X cs*uu* (Iso violation); = X = artefact ? Narrow. Anomalous decays “anti” phase space 23Slide24: (also M.Nowak et al, HADRON2003) Why in cs*? Which 1+? 2560 1+ 243MeV 25Slide25: DK D*K 26Slide26: Whatever makes scalar f_0(980) light (= just below KK) (compared to qq* p-wave) Probably makes scalar 2317 light (= just below DK) (compared to qq* p-wave) …and 2460 axial light (just below D*K) Production by easiest route: cs* residue Decays driven by di-meson DK D*K TEST: 1+ \to 0+ \gamma (M1) D*K \to DK \gamma = D* \to D \gamma S-wave meson-meson beats P-wave qq* (continued) 27Another novel state in : Another novel state in J^P=? 2632 Narrow. Anomalous decays “anti” phase space 28Novel states in : Novel states in J^P=0+,1-… 2632 cs* 1- radial (nodes); mix with ^3D_1 cs*uu* (Iso violation); cqs*q* + css*s*(tetraquark in 15_f) Narrow. Anomalous decays “anti” phase space 29Novel states in : Novel states in J^P=0+,1-… 2632 cs* 1- radial (nodes); mix with ^3D_1 doesn’t work cs*uu* (Iso violation); D_s + pi^o D_s + gamma gamma = NO cqs*q* + css*s*(tetraquark in 15_f) 6_f more attractive; D_s gamma gamma = NO Narrow. Anomalous decays “anti” phase space 30Slide30: 2632 would be here 31D_{sJ} summary: D_{sJ} summary 2317/2460: cs* 0+ 1+ seeds Meson-meson S-wave DK D*K Dynamics like 0++(980) 2632: artefact 32Some Reflections on Pentaquarks: Some Reflections on Pentaquarks 33Slide33: ½+ Strangeness +1 baryon mass 1540MeV narrow width Predicted!!! DPP In chiral soliton model with unusual assumptions Narrow width an enigma Mass a problem Production mechanism unknown n.b. expt has not established ½+ It might not exist! 34Slide34: u d u d Q* u d Jaffe Wilczek ud udQ* Karliner Lipkin L=1 L=1 Diquark attractions for unlike flavours = basis for pentaquark models (has not been demonstrated how low mass scalar diquarks form, stability, effective bosons, consistency with other hadron spectroscopy… etc. = ?) Pentaquarks (if they exist) = strong QCD correlations Slide35: Arndt Buccella Carlson Dyakanov Ellis Faber Giannini Huang Inoue Jaffe Karliner Lipkin Maltman Nussinov Oh Polyakov Qiang Rosner Stech Trilling U Veneziano Wilczek Xiang Yang Zhu If Theta doesn’t exist, then these (and many other theorists) should be congratulated on their creativityMass: Mass 37Slide37: + Baryon DPP original M=(1890-180Y)MeV and revised Linear only for 10*. Mixing with 8 complicates. Mass formulae beware |S| versus S. Strange quark costs too much No simple map onto pentaquarkSlide38: (LEPS) Anomalies with Theta Mass? F. Close and Q. Zhao, hep-ph/0404075 39Slide39: Mass Fitted. Not calculated Dyakanov Petrov Polyakov DPP assumed N(1710) in 10bar Jaffe Wilzcek JW assumed N(1440) as (ud)(ud)dbar X mass formula bizarre: q_5 10bar mass gap 1/3 m_s X pure 10bar not photoproduced from p X width 300MeV X gamma n:gamma p = radial 56plet qqq X Delta(1670) partner Karliner Lipkin KL assume cs* 200MeV orbital to set scale X spin averaged cs* costs 500MeV, Theta= 1800MeVSlide40: u d u d Q* u d Jaffe Wilczek ud udQ* Karliner Lipkin Q* \to (ud) = anomalous deuteron (ud) \to Q* 10bar mesons P-wave 1-+ etc? e.g.Chung Klempt Widths? FC Dudek Burns Forces ud very light and L large What mechanism? What if……..? 41Width: Width 42Slide42: Chiral Soliton Theta-N-K Coupling involves three unknowns A; B; C B F/D Set scale with g(10*) = 1-B-C NRCQM: F/D=2/3 B=1/5 C= 4/5 g(10*)=0 g(10*) C After Ellis Karliner Prasalowicz Width Slide43: Width < 10 MeV direct experiments <1MeV Cahn Trilling; Nussinov;… 3/2- Lambda(1520) KN width 7 MeV Jaffe Wilzcek; Jennings Maltman; Carlson et al; Close Dudek;Buccella Stora Color flavor spin overlap suppression > 24 X D wave; P-wave Lambda1600 is 100 MeV X needs qq* creation whereas qqqqq* falls apart X color killed by soft gluon exchange X spin flip costs little X flavor killed by rearrangement Stech et al; Dudek; Carlson et al Spatial overlap suppression X no dynamical proof Stech ? Strong color-spin forces (Dudek) + Stech model….? 44Slide44: Width < 10 MeV experiments <1MeV Cahn Trilling; Nussinov;… Decouples from KN (small width) Strong coupling to something (strong production) How is Theta produced? ………………enigma 45Production: Production 46Slide46: Several experimental limits in hadron production Some not restrictive yet e.g. psi(3095) to Theta Thetabar (=3080) versus LambdaLambdabar (1/100) or can be “explained away” e.g. psiprime sees some channels reduced and this is another one; big price to produce 10 q and q* etc. My opinion (this week) Limits in high statistics look impressive. Onus is on supporters to explain them away or find a loophole ……….example of a possible loophole Lipkin Karliner next 47Slide47: Why seen in photons but not in high statistics hadrons? CLAS: Theta+K = N*(2.4GeV) (24ev/10bgnd) Suppose N*(uddss*) and gamma provides the ss* Problems CLAS see in gamma pi K Theta pi N N* No memory of gamma(ss*); should apply to hadrons too…..why not CDF? SPring8 and CLAS1 too low E(gamma) to make 2.4GeV N* 48The Mystery of the Sigma_5: The Mystery of the Sigma_5 The case of the dog that didn’t bark (Sherlock Holmes) If Theta is real, why isnt Sigma_5 (or Sigma* ½+ 1660) also seen? 49Slide49: Note pKs can be + or + Decays Dyakanov Petrov Polyakov; Close Dudek; Oh Kim Lee generalises 50Slide50: Gamma N \to K Theta Assuming s,t,u and contact diagramsSlide51: Gamma N \to K Sigma5 FC-Q Zhao Slide52: 0.5 53Absence of Sigma_5, or even Sigma(1660) in experiments that claim Theta is a worry.: M(pKs) HERMES Absence of Sigma_5, or even Sigma(1660) in experiments that claim Theta is a worry.Slide54: Dzierba Szczepaniak Teige Fake Peaks in gamma N N gamma N a2/rho3 55Slide55: Dzierba Szczepaniak Teige Fake Peaks in gamma N N a2/rho3 N K K D/F wave decay forward back to KKbar a2/rho3 gives charge asymmetry Same velocity NK mass 1440 “real” kinematics broadens hump….Slide56: Dzierba Szczepaniak Teige One is real (CLAS) Three are fake Can you tell which?Slide57: (LEPS) Could this also explain different nK+ and pKs masses? F. Close and Q. Zhao, hep-ph/0404075 Show Dalitz plots!! Different Q values for charged neutral feed into mass of fake Theta?Slide58: Paradoxes; Enigmas; Hints of unreality How is Theta produced? Why seen in low statistics photoproduction but not in high statistics hadroproduction? Decouples from KN (small width) Strong coupling to something (strong production) Why does mass vary? real (dynamic clue); statistics (non existence clue) Cascades (exotics) studied since BQM Beware! K-Theta+ why no K+Sigma- Ks Theta+ why no Ks Sigma+ Why is production Theta/Sigma(1660) = infinity? 59CONCLUSION: CONCLUSION Have Weird Multiquark Demons been found? Is there a 1 MeV wide, S=+1 baryon at 1540 MeV? If NO this is testament to the ingenuity of theorists whose models can explain it even if it doesn’t exist. Lattice QCD is almost unique in not having definitively disproved that such a state does not exist. 60CONCLUSION: CONCLUSION Precision and variety = Beyond qq* Strong Glue in QCD: Glueballs mix; psi to gam gam V opportunity. exotic hybrids emerging; Xi_{c1} decays opportunity Multiquarks/Molecules: X(3872) 1++ molecule (to be disproved) Ds(2317;2460) 0+ and 1+: cs* or DK/DK* (need to determine) Ds(2635) artefact (to be disproved) Pentaquarks/Theta: Artefact or Strong QCD very profound Opportunity for lattice to realise its investmentCONCLUSION: CONCLUSION YES No Keep searching Have Weird Multiquark Demons been found? Democratic voting paper/Florida counting principle Slide62: With thanks to the organisers, the scientific secretaries and the IHEP students who have made our time in Beijing so enjoyableThis slide sponsored by Oxford University Press: This slide sponsored by Oxford University Press A Very Short Introduction to Particle Physics A little red pocket book with no equations for physics undergraduates and your partners by Frank Close 10 dollars at amazon.com nowSlide65: Central Production pp \to pMp 0+ and 2+ qq* G ? Compare e+e- \to e+(qq*)e-Slide66: A new narrow charmonium state B decay = a new source of charmonium Standard cc* theory wrong? Or is X(3872) not simple cc*? Charmonium problemsSlide67: A conjecture: T.Barnes, F.E.Close, H.J.Lipkin, hep-ph/0305025, PRD. Reminiscent of Weinstein and Isgur’s KKbar molecules, bound by level repulsion of the KKbar continuum against higher mass qqbar 0+ scalars at ca. 1.3 GeV.Slide68: Mass Low “N”(940) + “K”(495) (L=1) = 115MeV (ud)+(uds*) < “N+K” (L=1) = 200MeV Karliner Lipkin 2.59 2.56 2.32 2.11 1.97 1- 0+ Ds(cs*) spectrum 210Slide69: Mass Low “N”(940) + “K”(495) (L=1) = 115MeV (ud)+(uds*) < “N+K” (L=1) = 200MeV Karliner Lipkin 400-480 1- 0+ 0- 1+ L=0 L=1 2+ 2.55 -2.47 2.07 Spin averaged masses in multiplet Theta = 1750-1830Slide70: Unique Isospin laboratory I=3/2 and I=1/2 but for narrow states flavour wins: =(dss)dd* =(dss)uu* 10MeVSlide71: (LEPS) MΘ F. Close and Q. Zhao, hep-ph/0404075