1. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion1 Konstantin Goulianos The Rockefeller University & The CDF Collaboration Low-x Workshop, Nafplion, Greece, 4-7 June 2003 Introduction Run I review Run II results Conclusion Aspects of Diffraction at CDF

2. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion2 Introduction What is hadronic diffraction? X Diffraction dissociation KG, Phys. Rep. 101 (1983) 171 coherence

3. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion3  Non-diffractive interactions:  Diffractive interactions: rapidity gaps are regions of rapidity devoid of particles Gaps are exponentially suppressed From Poisson statistics: ( r =particle density in rapidity space) large rapidity gaps are signatures for diffraction rapidity gaps are formed by multiplicity fluctuations rapidity gaps, like diamonds, ‘live for ever’ Diffraction and Rapidity Gaps

4. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion4  Quark/gluon exchange across a rapidity gap: POMERON  No particles radiated in the gap: the exchange is COLOR-SINGLET with quantum numbers of vacuum  Rapidity gap formation: NON-PERTURBATIVE  Diffraction probes the large distance aspects of QCD: POMERON CONFINEMENT  PARTONIC STRUCTURE  FACTORIZATION ? The Pomeron

5. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion5  Elastic scattering  Total cross section  Diffraction PRD PRL PRL PRL 50 (1994) 5535 87 (2001)141802 to be sub’d submitted SOFT diffraction HARD diffraction Control sample W 78 (1997) 2698JJ 74 (1995) 855JJ 85 (2000) 4217 JJ 79 (1997) 2636JJ 80 (1998) 1156 b-quark 84 (2000) 232JJ 81 (1998) 5278 J/  87 (2001) 241802 JJ 84 (2000) 5043 JJ 88 (2002) 151802 with roman pots PRL reference PRD 50 (1994) 5518 PRD 50 (1994) 5550 Diffraction at CDF in Run I

6. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion6 Factorization & Renormalization Soft diffraction Renormalize to unity KG, PLB 358(1995)379 Gap probability  COLOR FACTOR Pomeron trajectory parton model

7. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion7 Reggeons Key players: Both rise at small  but integral does not fit data; M 2 -dependence of IP-IP-R does not fit low-s data; => KG: Renormalize IP-IP-IP Reggeon contribution: important at large  KG & JM: use renormalized IP-IP-IP plus  -IP with only g IP-IP-IP as free parameter

8. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion8 Total cross section KG, PLB 358 (1995) 379 Differential cross section KG&JM, PRD 59 (114017) 1999 REGGE RENORM s-independent  Differential shape agrees with Regge  Normalization is suppressed by factor ~  Renormalize Pomeron flux factor to unity M 2 SCALING Soft Single Diffraction Data

9. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion9 CDF Single Diffraction Data and Fits Data versus MC based on triple-Pomeron plus Reggeon CDF PRD 50 (1994) 5535 Data at |t|=0.05 GeV 2 corrected for acceptance KG&JM, PRD 59 (114017) 1999

10. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion10  Double diffraction  Plot #Events versus   Double Pomeron Exchange  Measure  Plot #Events versus log(  )  SDD: single+double diffraction  Central gaps in SD events Central and Double Gaps

11. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion11 Differential shapes agree with Regge predictions  One-gap cross sections require renormalization DDSDDDPE  Two-gap/one-gap ratios are Central and Double-Gap Results

12. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion12 Soft Double Pomeron Exchange

13. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion13 color factor 7 independent variables Gap probability Sub-energy cross section (for regions with particles) Integral Renormalization removes the s-dependence SCALING Two-Gap Diffraction (hep-ph/0205141)

14. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion14 5 region-centers 1 sum of all gaps 4 t-values V i 10 variables Renormalize gap probability to calculate multigap cross sections Use amplitude at t=0 for x-section Use amplitude squared for gaps P gap depends on sum of gaps form factors Renormalize: set integral of P gap to unity Amplitude one  factor for each gap Multigap Diffraction (hep-ph/0205141)

15. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion15 Hard diffraction in Run I BBC 3.2<  <5.9 FCAL 2.4<  <4.2 BBC FCAL Diffractive dijets CDF Forward Detectors

16. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion16  SINGLE DIFFRACTION  DOUBLE DIFFRACTION 1.45 (0.25) J/  0.62 (0.25)b 0.65 (0.04)0.75 (0.10)JJ 1.15 (0.55)W D0CDFX SD/ND gap fraction (%) at 1800 GeVDD/ND gap fraction at 1800 GeV All SD/ND fractions ~1% Gluon fraction Suppression by ~5 relative to HERA Just like in ND except for the suppression due to gap formation Hard Diffraction Using Rapidity Gaps

17. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion17 ISSUES: 1) QCD factorization > is F SD universal? 2) Regge factorization > (not detected) Bjorken-x of antiproton Nucleon structure function Diffractive structure function ? momentum fraction of parton in IP METHOD of measuring F SD : measure ratio R( ,t) of SD/ND rates for given ,t set R( ,t)=F SD /F ND evaluate F SD = R * F ND Diffractive Dijets with Leading Antiproton

18. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion18 Test Regge factorization Test QCD factorization Regge factorization holdsSuppressed at the Tevatron relative to predictions based on HERA parton densities !!! Dijets in Single Diffraction

19. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion19 (not detected) R(SD/ND) R(DPE/SD) Test of factorization equal? Factorization breaks down The second gap is un-suppressed!!! Dijets in Double Pomeron Exchange

20. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion20 Run II Diffraction at the Tevatron CDF Forward Detectors MiniPlug calorimeters (3.5<  <5.5) Beam Shower Counters (5.5<  <7.5) Antiproton Roman Pot Spectrometer

21. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion21 Run II Forward Detector Layout

22. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion22 MiniPlug Run II Data ADC counts in MiniPlug towers in a pbar-p event at 1960 GeV. “jet” indicates an energy cluster and may be just a hadron. Approximately 1000 counts = 1 GeV Multiplicity distribution in SD and ND events MiniPlug tower structure

23. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion23 J5At least one cal tower with ET > 5 GeV RP inclusiveThree-fold coincidence in RP trigger counters RP+J5Single Diffractive dijet candidates RP+J5+BSC-GAP_pDouble Pomeron Exchange dijet candidates Triggers  Results presented are from ~26 pb -1 of data  The Roman Pot tracking system was not operational for these data samples  The  of the (anti)proton was determined from calorimeter information: (-)+ is for (anti)proton Run II Data Samples

24. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion24 Diffractive Dijet Sample ND+SD & SD+MB overlap events  ~ 1 SD events 0.03<  <0.1 Flat region

25. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion25 Diffractive Dijet Structure Function Ratio of SD to ND dijet eventrates as a function of x Bj for different values of Q 2 =ET 2 Ratio of SD to ND dijet event rates as a function of x Bj compared with Run I data No  dependence observed within 0.03 <  <0.1 (confirms Run I result) No appreciable Q2 dependence observed within 100 < Q2 < 1600 GeV

26. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion26 Dijets in DPE In SD data with RP+J5 trigger select events with rapidity gap in both the BSC_p and MP_p (3.5 <  <7.5)

27. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion27 Data Selection DPE dijet candidatesDPE: RP+J5+BSC_GAP_p Single Diffractive dijet candidatesSD: RP+J5 Tower with ET > 5 GeV ND: J5 Prescale=5 Prescale=280

28. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion28 DPE Dijet Kinematics

29. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion29 Inclusive/Exclusive DPE Dijet Predictions

30. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion30 Limit on Exclusive DPE Dijets (Run I) Observed ~100 DPE dijet events  0.035 <  < 0.095  Jet E T > 7 GeV  Rapidity gap in 2.4 <  < 5.9 Dijet mass fraction M JJ based on energy within cone of 0.7 => look for exclusive dijets in window 0.7 < R JJ < 0.9

31. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion31 Run II: Exclusive DPE Dijets ? No exclusive dijet bump observed

32. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion32 Double Pomeron Exchange Dijet Events Rjj=0.81, Jet1(2)=33.4(31.5) GeVRjj=0.36, Jet1(2)=36.2(33.3) GeV

33. 4-7 June 2003K. Goulianos, Low-x Workshop, Nafplion33 SUMMARY Soft and hard conclusions b Soft Diffraction e Hard Diffraction  Pay a color factor  for each gap Use the reduced energy cross section Get gap size from renormalized P gap Diffraction is an interaction between low-x partons subject to color constraints