BINP for FAIR

1. Yu.Shatunov BINP for FAIR Moscow 17-18 May 2006

2. Research and Development Contractbetween GSI and BINP Subject and Objectives of the Contract 1. Kickers for synchrotrons and storage rings 2. Septum magnets for synchrotrons and storage rings 3. Technical design of ER and interaction region for collider mode including modification for AIC/NUSTAR 4. Luminosity monitor and electron spectrometer for ELISE/NUSTAR • Pbar-Target and Collection • Ultra Cold Electron Target for NESR • Prototype High Voltage Section for the NESR Electron Cooler • Resistive coil magnets for FAIR • Production of vacuum chambers for SIS18 quadrupoles (addressed in EU-FP 6 Construction contract No. 515876) • Study for High radiation resistant magnets for Super-FRS (R&D contract No. RU/03533872/SE-05007 is already placed) • Prototype Design for the RF-Cavities at SIS100 /300 (Continuation of the study with purchase order No. 4500054244)

3. BINP for FAIR • Super-FRS target high radiation resistant magnets • Electron-ions collider (eA) e-linac electron spectrometer P_bar-ions collisions • Electron colling: NESR (e-coller, e-target); e-cooler for P_bar –A collider, HESR e-cooler • Kickers for synchrotrons and storage rings • Septum for synchrotrons and storage rings • Superferric dipole and quads for CR • RF for SIS-100 (300) • Polarized P-P_bar collider at HESR

4. SIS-100(300) pulse dipole septums, kickers RF SIS-18 vacuum chamber target, magnets e-cool P-P_bar collider EIC AIC CR quads e-cool

5. Layout and Design Parameters of the Super-FRS Design Parameters • The main technical challenges • are at the Pre-Separator • The physical performance of • the new facility can be directly • deduced from the experience • with the FRS

6. First stage of Super-FRS Q Q S Q ΔBρ/Bρ beam production target

7. High power target based on liquid lead alloy technology • Shaft cooling unit (tested on 75 kW beam power) •Operating temperature range (300-400°C) provides annealing of radiation damages in all corresponding subsystems. •It provides cheap and reliable solution for bearings and rotation feed-through in high radiation area.

8. High radiation resistant dipole magnet MO Cu Power ~ 120 kWWeight~ 90 t

9. High radiation resistant sextupole magnet

10. e-A collider

11. spherical abberations 10% of full (azimuthal) angle coverage Full tracking simulation including detectors A Spectrometer  dp/p = 2 10-4 (magnets cost 1.5 MEuro) e

15. Quads for CR CR superferric quadrupole (wide) CR septum quadrupole

16. Superconducting septums for SIS-100 1T Lambertson magnet 3T septum magnet (fast)

17. SIS 100 extr/emrg kicker 2D simulations. Magnetic field, A/m, 0-10e5 Ceramic vacuum chamber Ferrite8C11 more homogeneous field nonhomogeneous field Busbars Simulations based on TR-Nov-2005 report. BINP proposal.

18. SIS 100 extr/emrg kicker 3D simulations. Magnetic field, A/m, 0-10e5

19. Design of RF-station for SIS-100 (10-th harmonic) Frequency range 1.1-2.7 MH RF voltage 19 kV Ferrite type 400 NN-2 Number of ferrite for unit 68 Number of unit 29 Cost per unit 0.5 Euro

20. Conceptual Design for a PolarizedProton-Antiproton Collider Facility at HESR

21. Layout of the P-P_bar collider 1212 bunches

22. …… for BINP M€ • Super-FRS target 0.5 high radiation resistant magnet 1.3 • Electron-ions collider (eA) e-linac + ring 4.5 + 3.5 electron spectrometer (magnets) 1.5 P_bar-ions collisions 2.0 • Electron cooling: NESR (e-cooler, e-target) 4.0 e-cooler for P_bar –A collider, 0.5 HESR e-cooler 5-7 • Kickers for synchrotrons and storage rings 0.2/per unit • Septum for synchrotrons and storage rings • Superferric dipole and quads for CR • RF for SIS-100 (300) 0.5/per unit • Polarized P-P_bar collider at HESR + 17.0