Introduction

1. Introduction

2. November 2002

3. Good News

4. House Senate

5. References All of the above can be downloaded from our website Go to “Documents” - top of left frame:

6. Periodic Table n n p p

7. Spectroscopy of the Atom

8. Discovery of the Hadrons In the 50’s and 60’s physicists discovered over 100 elementary particles incosmic ray showers and accelerators. Almost all of these were short-livedand were classified as mesons or baryons. Bubble chamber photo Typical lifetime:10-23 s Baryons have half-integer spin and obey Pauli Exclusion Principle (PEP). They are fermions. Mesons have integer spin and do not obey the PEP. They are bosons.

9. Discovery of Elementary Particles in showers of Cosmic Rays

10. Spectroscopy of Hadrons proton neutron π meson Baryons Mesons

11. Standard Model Electromagnetic force explains atoms Ordinary Matter Strong Force binds quarks Electroweak force explains radioactivity

12. Subatomic Sizes

13. Color

14. No Free Quarks Color Field: Because of self interaction, confining flux tubes form between static color charges

15. Lattice Calculations and Flux Tubes From G. Bali: quenched QCD with heavy quarks

16. Flux Tube Breaking

17. Exciting the Flux Tube There are two degenerate first-excited transverse modes with J=1– clockwise and counter-clockwise – and their linear combinations lead toJPC = 1– + or JPC=1+ – for the excited flux-tube Normal meson:flux tube in ground state Excitedfluxtube

18. The Light Quarks and Light Mesons JPC = 0– +0++1– – 1+ –2++ … Allowed combinations JPC = 0– –0+ –1– +2+ – … Not-allowed: exotic Expect to find nine mesons with the same J, P, C - a nonet

19. Quantum Numbers for Hybrid Mesons Exotic Excited Flux Tube Quarks Hybrid Meson like like So only parallel quark spins lead to exotic JPC

20. QCD and Spectroscopy

21. Exotic Hybrids Will Be Found More Easily in Photoproduction There are strong indications from theory that photons will produceexotic hybrid mesons with relatively large cross sections. Production of exotichybrids favored.Almost no data available Quark spins already aligned

22. Coherent Bremsstrahlung Incoherent & coherent spectrum 40% polarization in peak collimated tagged with 0.1% resolution 12 GeV electrons flux This technique provides requisite energy, flux and polarization Linearly polarized photons out electrons in spectrometer diamond crystal photon energy (GeV)

23. Tagger Magnet

24. Aerial View of Jefferson Lab

25. Linac

26. Cryomodule

27. Arcs

28. Helium Factory

29. UpgradePlan

30. Detector

31. Lead GlassCalorimeter &Magnet Magnet arrives in Bloomington

32. Electronics PMT Bases: FADCs: Electronics assemblyrobotics facility to be installed at IU in June

33. TOF Prototype $70K from JLab

34. Magnetic Shielding Helmholtz coils built by undergrads lastyear - upgraded this year new power supplies

35. Collaboration History • Founded in 1998 • Workshops (latest in May 2003) • 4th Design Report • Collaboration meetings • Regular conference calls • Management plan • Collaboration Board Reviews • PAC12 • Cassel Review • APS/DNP Town Meeting • NSAC LRP • PAC23

36. Computational Challenge • GlueX will collect data at 100 MB/sec or 1 Petabyte/year - comparable to LHC-type experiments. • Close collaboration with computer scientists has started and the collaboration is gaining experience with processor farms.

37. Conclusions The spectroscopy of light quark mesons is on the verge of makingimportant contributions to answering a fundamental question: What is the nature of confinement in QCD? We welcome additional collaborators - theory and experimentand bright, enthusiastic undergrads