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H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 1 GSI UHV System Upgrade The GSIThe GSI Future Accelerator Facility for Beams.

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Presentation on theme: "H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 1 GSI UHV System Upgrade The GSIThe GSI Future Accelerator Facility for Beams."— Presentation transcript:

1 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 1 GSI UHV System Upgrade The GSIThe GSI Future Accelerator Facility for Beams of Ions and Antiprotons SIS18 UHV Status SIS18 UHV Upgrade Ion Induced Desorption SIS100 / SIS300 : Cryogenic UHV see also: O. Boine-Frankenheim: "The international Accelerator Project at GSI" A. Krämer: "Ion Induced Desorption Yield Measurements at GSI" E. Mustafin: "Theory of Dynamic Vacuum Instability Induced by Lost Heavy Ions in Accelerator Rings"

2 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 2 The GSI The GSI Future Accelerator Facility for Beams of Ions and Antiprotons Acceleration I IIIII Experiments 100m n From protons to uranium n In future also antiprotons n 1 MeV/u to 2 GeV/u n In future up to 30 GeV/u n 10 9 to 10 11 particles/cycle n In future 10 12 particles/cycle n 0.1 Hz to 1 Hz Repetition rate n In future up to 3 Hz  Multi-user operation: pulse to pulse 3ion species, full energy range n Nuclear and Hadron Physics n Nuclear Chemistry n Atomic Physics n Material Science n Plasma Physics n Biophysics see: O. Boine-Frankenheim: "The international Accelerator Project at GSI"

3 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 3 The GSI The GSI Future Accelerator Facility for Beams of Ions and Antiprotons

4 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 4 GSI International Accelerator Facility UHV system requirements Due to ion beam lifetime requirements (e.g.: U 28+ in SIS18): SIS18: warm p≈5·10 -12 mbar ESR: warm p≈5·10 -12 mbar SIS100: cold arcs T=7-20K warm straight sections T=300K p≈5·10 -12 mbar SIS300: cold arcs T=4.2K warm straight sections T=300K p≈5·10 -12 mbar NESR: p≈5·10 -12 mbar HESR: p≤10 -10 mbar RESR: p≤10 -10 mbar CR: p≤10 -10 mbar HEBL: length 2.5 km, 70% cold *all pressures: N 2 equivalent SIS100/300 HESR NESR CR RESR from SIS18

5 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 5 The heavy ion synchrotron SIS present status n 12 sectors each: n 18 m long n  200 mm n 4 TSP n 3 Ion pumps (triode type) n 1-2 extractor gauge n 7 vacuum sectors n One pumping station with turbo molecular pump (rough pumping + bake- out) n 1 RGA

6 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 6 SIS18 residual gas composition (10/2003) RGA spectra examples Ar CxHy S03 total pressure: 3*10 -12 mbarS08 total pressure: 6.8*10 -11 mbar  existing "micro-leaks"and contaminations

7 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 7 Static conditions: SIS18 UHV Status, october 2003 (no ion beam operation) injection extraction Contamination of Ar, Hydrocarbons

8 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 8 Dynamic Vacuum and Beam Lifetime Desorption processes degenerate the residual gas pressure ( U 28+ case ) Initiated by :  Systematic beam losses on acceptance limiting devices (septa) ( 8MeV/u < E <100MeV/u )  Stripped beam ions ( 8MeV/u < E <100MeV/u )  Ionized and accelerated residual gas ( E < keV) : minor effect  losses increase with number of injected ions ( shorter beam life time due to stronger pressure bumps )  Even at “zero current” ion beam lifetime is to short P. Spiller, December 2001 8.75 MeV/u U 28+

9 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 9 U 28+ ion beam operation: total ion beam loss inside first dipole S01  local pressure rises do not strongly influence neighbouring UHV sections  Easy measurement at other maschines could help to get high energy data for desorption processes

10 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 10 U 73+ ion beam operation

11 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 11 U 28+ / U 73+ operation, RGA diagnostic S01 [CO] U28+, detecated ion beam loss in S01MU1 U73+ maschine exp., H.Damerau, failure of dipoles at 12000 no ion beam, service ion source U73+, H. Damerau, machine experiments no ion-beam in SIS (4:00 to 8:00pm) U73+, U.Blell, machine experiments. Maschinenexperimente 5.6.2002 Ion: U73+, U28+ Energien : 11,17 MeV/u (73+) ; 8,7MeV/u (28+) Messort: Prisma RGA in S01VK4 Messzeit: 5.6.2002 13:00 bis 6.6.2002 12:00Uhr Bemerkungen: in der Zeitskala bis ca. 10000sec wurde U28+ mit 8,7MeV/u gezielt in S01MU1 verloren: Puls 48muA, 200mus, Zykluszeit:ca. 1,8s in der Zeitskala von 10000 bis 85000 fanden Maschinenexperiment e (Damerau,Blell) mit U73+ statt nachfolgend sind die aufgenommen Langzeitspektren dargestellt nur für die Masse 28 (CO, N2) ist ein signifikanter Anstieg des Partialdrucks korreliert mit dem Strahlbetrieb zu beobachten

12 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 12 U 28+ ion beam operation of SIS18 (up to 10 10 injected ions)

13 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 13 Lifetime of U 28+ ions in SIS18 at low ion beam intensities (~ 10 8 ions per cycle) R. Olson et al., GSI Annual Report 2002, 97 (2003)

14 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 14 Vacuum Requirements for SIS18 Beam lifetime has to be significantly larger than cycling time of the SIS18 (Lifetime of at least 10 seconds for all kinds of operation) Total pressure in low 1∙10 -12 mbar with a small fraction of high Z gases even for highest beam intensities optimized dynamic conditions: efficient ion beam loss control, low desorption at localized ion beam losses, maximized local pumping speed at locations of ion beam loss, No beam scrubbing possible due to multi-user operation of SIS18 optimized static conditions: minimized outgassing rate through material and production control, cleaning, bakeout, removal of contaminations and "micro- leaks" efficient and distributed pumping.

15 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 15 Optimized Static Conditions: 2004200520062007 Detection and removal of micro-leaks (  Ar !) Exchange of contaminated insertions (  CxHy) Replacement of all 24 dipole chambers (  bakeout to 300°C, coating?) [existing new spare chambers] Replacement of all 12 quadrupole chambers (  bakeout to 300°C, coating?) [prototype and new chambers to be designed and built] Ion Pumps: optimized IP regeneration, if necessary: replacement by noble diodes, optimized sublimation cycles (  improved pumping speed)

16 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 16 Optimized Dynamic Conditions:  collimators at locations of known ion beam loss: injection section / septum extraction / septum  with integrated high pumping speed: - cryopump  low desorption materials: - experiments at test bench with ion beam  distributed pumping speed: - NEG ? May/June 2003 since April 2003 beginning of 2004 final decision depends on desorption experiment results

17 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 17 Cryogenic Systems: Nuclotron Dipole for SIS100 elliptical, 130x65mm indirectly cooled with pipes and LHe, T=7-20K  p=1bar => 0.8mm stainless steel wall dB/dt=4T/s => 0.5mm stainless steel wall (eddy current) Alternative: conventional warm magnets with warm beam pipe In the straight sections of SIS100 (6x60m) the vacuum chambers are at room temperature.

18 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 18 Cryogenic systems: RHIC Dipole for SIS300 round, diameter=100mm directly cooled in LHe-bath, T=4.2K for quench protection  p=30bar dB/dt=1T/s

19 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 19 Requirements for warm (T=300K) vacuum beam pipes in SIS100/300 UHV compatible (outgassing rate: 10 -13 mbarl/(s cm 2 )) low desorption rate under ion bombardment high electric conductivity (image current guidance, impedance) non-magnetic, non-magnetizable good weldability or other UHV compatible joining techniques, good machinability moderate costs good thermal conductivity high mechanical stability at high temperature [bake out @573K for stainless steel] low thermal expansion Some (in principle) possible materials: Stainless steel, aluminum and aluminum alloys (?), copper and copper alloys (Al-Cu), titanium and titanium alloys, beryllium(???)

20 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 20 Comparison cold and warm vacuum chambers Cold Vacuum ChambersWarm Vacuum Chambers Ion Induced Desorption  H 2 + ->H 2  ≈10 3 -10 5 @ 0.5- 10keV no high energy ion induced desorption data available!! But no pressure increase observed in cold sections of RHIC! (?) H 2 + ->H 2  ≈1 @ 0.5keV (impact of secondary residual gas ions)  ≈10 3 -10 6 @ 1 MeV/u-10 GeV/u (primary high energy ions) Pumping speed corresponds to sticking coefficient Sticking Coefficient @ T= 5-20K H 2 : < 0.5 CO: ~ 1 CO 2 : ~ 1 CH 4 : ~ 1 NEG H 2 : 0.007 CO/CO 2 : 0.5 no pumping speed for chemical inert gases (Ar, CH 4,...)

21 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 21 Open Questions Warm Vacuum Sections:  Ion induced desorption yield at high energies? (experimental program under way at the test bench and at SIS18 directly) Next step: Measurements at UNILAC, ERDA analysis of targets  Electron cloud effects? Cold Vacuum Sections:  Ion induced desorption yields at 4K for different materials? (experimental program under way)  Required wall thickness and material for cold chambers in fast ramped magnets? (image current, eddy current, additional supports, heat load, impedance, field quality...) (first studies at University of Magdeburg). Next steps: construction / manufacturing / testing of vacuum chamber samples  prototyping

22 H. Reich-Sprenger, 13th ICFA Beam Dynamics Mini-workshop 9-12 December.2003 22 Possible UHV collaboration inputs NEG coating of vacuum chambers (SIS-dipole, 4-pole,... ?) experiments on low desorption yield materials design work on cryogenic vacuum chambers (SIS100,SIS300) Material/surface physics input to understand the desorption physics........ GSI UHV group: M. Bender, M. Bevcic, P. Gaj, P. Horn, R. Kaminski, H. Kollmus, A. Krämer, J. Kurdal, H. Reich-Sprenger, H. Rittelmeyer, G. Savino, K. Welzel

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