GSI Future Facility Walter F. Henning March 2003, LEAP03

1. GSI Future Facility Walter F. Henning March 2003, LEAP03 • Introduction • Facility Layout and Characteristics • Scientific Areas and Goals • Research with Antiprotons • Summary

2. GSI Future Facility SIS 100/200 SIS UNILAC FRS ESR HESR Super FRS CR NESR 100 m

3. SIS UNILAC FRS ESR Upgrade towards the Future Facility Freqency (power): 0.3 Hz 3 Hz Space charge reduction (vacuum): U73+ U28+ Present GSI Facility Accelerator Parameters Energies: Unilac < 20 MeV/u SIS 1-2 GeV/u ESR < 0.8 GeV/u 3 Injectors HSI: 8 mA Ar1+ 18 mA Ar10+ 15 mA U4+ 2,5 mA U28+ 0,5 mA U73+

4. GSI Facility Characteristics

5. GSI Facility Characteristics Primary Beams • 1012/s; 1.5 GeV/u; 238U28+ • Factor 100-1000 over present in intensity • 2(4)x1013/s 30 GeV protons • 1010/s 238U73+ up to 25 (- 35) GeV/u

6. Key Technical Features • Cooled beams • Rapidly cycling superconducting magnets GSI Facility Characteristics Primary Beams • 1012/s; 1.5 GeV/u; 238U28+ • Factor 100-1000 over present in intensity • 2(4)x1013/s 30 GeV protons • 1010/s 238U73+ up to 25 (- 35) GeV/u Secondary Beams • Broad range of radioactive beams up to 1.5 - 2 GeV/u; up to factor 10 000 in • intensity over present • Antiprotons 3 (0) - 30 GeV Storage and Cooler Rings • Radioactive beams • e – A collider • 1011 stored and cooled 0.8 - 14.5 GeV antiprotons

7. SIS 100/200 FuE: Pulsed superconducting magnets 2T, 4T/s 4 (6)T, 1 (2)T/s

8. Storage Rings Collector (CR) and Storage Rings (NESR) for Ions and Antiprotons

9. HESR - High Energy Storage Ring Characteristics 1011 stored antiprotons 0.8 - 14.5 GeV L = 2 x 1032 p/p ≥ 10-5 x/x ≥ 100m

10. electron collector electron gun electron collector electron gun high voltage platform high voltage platform magnetic field electron beam electron beam magnetic field ion beam ion beam Storage Rings: Cooled Ion Beams

11. electron collector electron gun high voltage platform magnetic field electron beam ion beam Storage Rings: Cooled Ion Beams

12. electron collector electron gun high voltage platform magnetic field electron beam ion beam Storage Rings: Cooled Ion Beams

13. electron collector electron gun high voltage platform magnetic field electron beam ion beam Storage Rings: Cooled Ion Beams

14. electron collector electron gun high voltage platform magnetic field electron beam ion beam Storage Rings: Cooled Ion Beams before cooling after cooling ion intensity 1.03 0.97 1 rel. ion velocity v/v0

15. electron collector electron gun before cooling after cooling high voltage platform ion intensity magnetic field electron beam 1.03 0.97 1 ion beam rel. ion velocity v/v0 Storage Rings: Cooled Ion Beams

16. electron collector electron gun before cooling after cooling high voltage platform ion intensity magnetic field electron beam 1.03 0.97 1 ion beam rel. ion velocity v/v0 Storage Rings: Cooled Ion Beams

17. electron collector electron gun before cooling after cooling high voltage platform ion intensity magnetic field electron beam 1.03 0.97 1 ion beam rel. ion velocity v/v0 Storage Rings: Cooled Ion Beams

18. electron collector electron gun before cooling after cooling high voltage platform ion intensity magnetic field electron beam 1.03 0.97 1 ion beam rel. ion velocity v/v0 noise power density a.u. frequency [Hz] Storage Rings: Cooled Ion Beams

19. electron collector electron gun before cooling after cooling high voltage platform ion intensity magnetic field electron beam 1.03 0.97 1 ion beam rel. ion velocity v/v0 Storage Rings: Cooled Ion Beams

20. electron collector electron gun before cooling after cooling high voltage platform ion intensity magnetic field electron beam 1.03 0.97 1 ion beam rel. ion velocity v/v0 Storage Rings: Cooled Ion Beams

21. electron collector electron gun before cooling after cooling high voltage platform ion intensity magnetic field electron beam 1.03 0.97 1 ion beam rel. ion velocity v/v0 Storage Rings: Cooled Ion Beams

22. electron collector electron gun before cooling after cooling high voltage platform ion intensity magnetic field electron beam 1.03 0.97 1 ion beam rel. ion velocity v/v0 Storage Rings: Cooled Ion Beams

23. Parallel Operation Radioactive Beams Plasma Physics 100 Tm Ring 200 Tm Ring Collector & Storage Ring High-Energy Storage Ring Nucleus-Nucleus 100 sec Antiprotons Duty-Cycles of the Accelerator Rings Duty-Cycles of the Physics Programs Radioactive Beams Nucleus-Nucleus Collisions Antiprotons Plasma-Physics 0% 50% 100%

24. Proton-rich nuclei • Proton radioactivity • Proton - neutron pairing • Isospin symmetry • Tests of standard model and symmetries • Nucleosynthesis • Superheavy elements • Shell stabilization • Long-lived nuclei • Neutron-rich nuclei • Neutron drip line • Shell quenching • Skins and halos • Loosley bound systems • Soft collective modes • Nucleosynthesis Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries

25. Accreting white dwarf Elements in our solar system Nova Cygni 1992 Proton number Z Sun Neutron number N Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries

26. Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries

27. Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries Hadron Structure and Quark-Gluon Dynamics - Antiprotons Non-pertubative QCD Quark-gluon degrees of freedom Confinement and chiral symmetry

28. Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries Hadron Structure and Quark-Gluon Dynamics - Antiprotons Non-pertubative QCD Quark-gluon degrees of freedom Confinement and chiral symmetry

29. Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries Hadron Structure and Quark-Gluon Dynamics Non-pertubative QCD Quark-gluon degrees of freedom Confinement and chiral symmetry Nuclear Matter and the Quark-Gluon Plasma - Relativistic HI - Beams Nuclear phase diagram Compressed nuclear/strange matter Deconfinement and chiral symmetry

30. Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries Hadron Structure and Quark-Gluon Dynamics - Antiprotons Non-pertubative QCD Quark-gluon degrees of freedom Confinement and chiral symmetry Nuclear Matter and the Quark-Gluon Plasma - Relativistic HI - Beams Nuclear phase diagram Compressed nuclear/strange matter Deconfinement and chiral symmetry

31. Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries Hadron Structure and Quark-Gluon Dynamics - Antiprotons Non-pertubative QCD Quark-gluon degrees of freedom Confinement and chiral symmetry Nuclear Matter and the Quark-Gluon Plasma - Relativistic HI - Beams Nuclear phase diagram Compressed nuclear/strange matter Deconfinement and chiral symmetry Physics of Dense Bulk Matter - Bunch Compression Properties of high density plasmas Phase transitions and equation of state Laser - ion interaction with and in plasmas

32. Magnetic Fusion Inertial Cofinement Fusion Sun Core Temperature [eV] PHELIX Laser Heating Ideal plasmas Strongly coupled plasmas Ion Beam Heating Jupiter SIS 18 solid state density Sun Surface Density [cm-3] Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries Hadron Structure and Quark-Gluon Dynamics - Antiprotons Non-pertubative QCD Quark-gluon degrees of freedom Confinement and chiral symmetry Nuclear Matter and the Quark-Gluon Plasma - Relativistic HI - Beams Nuclear phase diagram Compressed nuclear/strange matter Deconfinement and chiral symmetry Physics of Dense Plasmas and Bulk Matter - Bunch Compression Properties of high density plasmas Phase transitions and equation of state Laser - ion interaction with and in plasmas

33. Magnetic Fusion Inertial Cofinement Fusion Sun Core Temperature [eV] PHELIX Laser Heating Ideal plasmas Strongly coupled plasmas Ion Beam Heating Jupiter SIS 18 solid state density Sun Surface Density [cm-3] Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries Hadron Structure and Quark-Gluon Dynamics - Antiprotons Non-pertubative QCD Quark-gluon degrees of freedom Confinement and chiral symmetry Nuclear Matter and the Quark-Gluon Plasma Nuclear phase diagram Compressed nuclear/strange matter Deconfinement and chiral symmetry Physics of Dense Plasmas and Bulk Matter - Bunch Compression Properties of high density plasmas Phase transitions and equation of state Laser - ion interaction with and in plasmas Ultra High EM-Fields and Applications - Ions & Petawatt Laser QED and critical fields Ion - laser interaction Ion - matter interaction

34. Magnetic Fusion Inertial Cofinement Fusion Sun Core Temperature [eV] PHELIX Laser Heating Ideal plasmas Strongly coupled plasmas Ion Beam Heating Jupiter SIS 18 solid state density Sun Surface Density [cm-3] Summary of Research Areas at the GSI Future Facility Structure and Dynamics of Nuclei - Radioactive Beams Nucleonic matter Nuclear astrophysics Fundamental symmetries Hadron Structure and Quark-Gluon Dynamics - Antiprotons Non-pertubative QCD Quark-gluon degrees of freedom Confinement and chiral symmetry Nuclear Matter and the Quark-Gluon Plasma - Relativistic HI - Beams Nuclear phase diagram Compressed nuclear/strange matter Deconfinement and chiral symmetry Physics of Dense Plasmas and Bulk Matter - Bunch Compression Properties of high density plasmas Phase transitions and equation of state Laser - ion interaction with and in plasmas Ultra High EM-Fields and Applications - Ions & Petawatt Laser QED and critical fields Ion - laser interaction Ion - matter interaction

35. HESR - High Energy Storage Ring Characteristics 1011 stored antiprotons 0.8 - 14.5 GeV L = 2 x 1032 p/p ≥ 10-5 x/x ≥ 100m

36. Quark-Gluon Structure of Hadrons

37. Confining potentiales Quark-Gluon Structure of Hadrons

38. Confinement Quark-Gluon Structure of Hadrons

39. Mass of hadrons Confinement Quark-Gluon Structure of Hadrons

40. Mass of hadrons Confinement Quark-Gluon Structure of Hadrons

41. Mass of hadrons Chiral symmetry and quark condensate Confinement SPS g,p-,p - beams RHIC LHC SIS 18 SIS 200 T [MeV] 300 Quark-Gluon Structure of Hadrons

42. Mass of hadrons Chiral symmetry Confinement |<qq>| SPS g,p-,p - beams RHIC LHC SIS 18 SIS 200 T [MeV] 300 Quark-Gluon Structure of Hadrons

43. Mass of hadrons Meson Hybrid Glueball Glueballs Hybrids Chiral symmetry Signal: exotic quantum numbers: partial wave analysis normal quantum numbers: model comparison (LGT) Confinement ggg qq qqg Normal meson: 2 fermions P = (-1)L+1 C = (-1)L+S Excited glue: bosonic degree of freedom → exotic quantum numbers eg. JPC=1-+, 0--, 0+-, 2+-… → normal quantum numbers |<qq>| SPS g,p-,p - beams RHIC LHC SIS 18 mixing with normal mesons charm sector: few resonances with small widths SIS 200 T [MeV] 300 Quark-Gluon Structure of Hadrons

44. Mass of hadrons Chiral symmetry Confinement |<qq>| SPS g,p-,p - beams RHIC Glueballs / Hybrids LHC SIS 18 SIS 200 T [MeV] 300 qq qqg Quark-Gluon Structure of Hadrons

45. Mass of hadrons Chiral symmetry Confinement |<qq>| SPS g,p-,p - beams RHIC Glueballs / Hybrids LHC SIS 18 SIS 200 T [MeV] 300 qq qqg Quark-Gluon Structure of Hadrons Double Strangeness

46. Mass of hadrons Double Strangeness Chiral symmetry Confinement |<qq>| SPS g,p-,p - beams RHIC Glueballs / Hybrids LHC SIS 18 SIS 200 T [MeV] 300 qq qqg Quark-Gluon Structure of Hadrons

47. Mass of hadrons Energy (mass) range covered by new GSI facility p momentum [GeV/c] Two-body Thresholds Molecules Gluonic Excitation Mesons Double Strangeness Chiral symmetry Confinement |<qq>| Light Mesons SPS Charmonium g,p-,p - beams RHIC Glueballs / Hybrids LHC SIS 18 SIS 200 T [MeV] 300 qq qqg Mass [GeV/c2] Quark-Gluon Structure of Hadrons

48. Mass of hadrons p momentum [GeV/c] Two-body Thresholds Molecules Gluonic Excitation Mesons Double Strangeness Chiral symmetry Confinement |<qq>| Light Mesons SPS Charmonium g,p-,p - beams RHIC Glueballs / Hybrids LHC SIS 18 SIS 200 T [MeV] 300 qq qqg Mass [GeV/c2] Quark-Gluon Structure of Hadrons

49. Mass of hadrons HESR - High Energy Storage Ring p momentum [GeV/c] Two-body Thresholds Molecules Gluonic Excitation Mesons Double Strangeness Chiral symmetry Confinement |<qq>| Light Mesons SPS Charmonium g,p-,p - beams RHIC Glueballs / Hybrids LHC SIS 18 SIS 200 T [MeV] 300 qq qqg Mass [GeV/c2] Quark-Gluon Structure of Hadrons

50. Mass of hadrons p momentum [GeV/c] Two-body Thresholds Molecules Gluonic Excitation Mesons Double Strangeness Chiral symmetry Confinement |<qq>| Light Mesons SPS Charmonium g,p-,p - beams RHIC Glueballs / Hybrids LHC SIS 18 SIS 200 T [MeV] 300 qq qqg Mass [GeV/c2] Quark-Gluon Structure of Hadrons