Progress on Ion Beam Focusing with Bent Crystals at the H8-RD22 Experiment at CERN

1. Walter Scandale CERN For the H8-RD22 collaboration (CERN, FNAL, INFN, IHEP, JINR, PNPI) ALICE seminar 30 April 2007 H8-RD22 Experiment:progress on ion beam focusing with bent crystals We acknowledge the support of the European Community-Research Infrastructure Activity under the FP6 “Structuring the European Research Area” programme (CARE, contract number RII3-CT-2003-506395). Walter Scandale

2. Outlook • Reminder of the concept of collimation • Why using crystals • The H8-RD22 experiment at CERN • Silicon crystals • Experimental layout • High precision goniometric system • Tracking detectors • The results of the 2006 run • Crystal Angular Scans (Strip and Quasi-Mosaic Crystals) • Double Reflection Effect • Concluding remarks and future plans Walter Scandale

3. Walter Scandale Two stage collimation Beam propagation Beam Core Primary halo (p) Secondary halo p p p Tertiary halo Impact parameter ≤ 1 mm p e Secondary collimator (massive absorber) Primary collimator (scatterer) p Shower e Sensitive equipment Shower

4. Walter Scandale Two stage collimation phase space x’ Capture condition: Secondary collimator (conversion in hadr. shower ) Primary collimator (scatterer) x’ x x’ mainly due to multiple Coulomb scattering, with <x’2>~ L   N N 2 1 • short primary scatterer • longer secondary collimator downstream with larger gap aperture • halo particles captured through amplitude increase via multiple scattering and multi-turn effect. Curtesy of Bellodi

5. Walter Scandale Requirements for LHC Courtesy of R. Assmann

6. Walter Scandale Collimation aperture Courtesy of R. Assmann Open problems: • Resistive impedance (up to 100 times the whole LHC) • Electron cloud (local concentration) IR3 and IR7 insertions are equipped with 54 collimators made of carbon-carbon

7. Walter Scandale LHC stability diagram All the machinewith Cu coated (5 mm)collimators All the machine Without collimators (TCDQ+RW+BB) Courtesy of E. Metral

8. Walter Scandale Ion collimation: why an issue? Nominal ion beam has 100 times less beam power than proton beam, but particle-collimator physics very different: ~20 times higher probability of nuclear interactions respect to p A new disturbance respect to p High probability to undergo nuclear interactions in the scatterer before 2-stage collimation condition is satisfied Large variety of daughter nuclei, Monte Carlo calculated specific x-sections loss 1 n (59%) 207Pb or 2 n (11%) 206Pb Curtesy of Bellodi

9. Walter Scandale Ion collimation: what can fail? Typical transverse momentum transferred in NF ~ 1 A∙MeV/c, even smaller for ED processes (compared to ~10 A∙MeV/c due to beam emittance). After first impact/grazing with scatterer: • high probability of nuclear interactions • production of isotopes with different Z/A ratio and momentum and direction almost unchanged • secondary ions not intercepted by the secondary and lost downstream in SC magnets because of different Br LHC energy acceptance: - arcs: ~ ±1% - IR3: ~ ±0.2% Curtesy of Bellodi

10. Walter Scandale Loss map from computer simulations ~50% current limiton nominal 208Pb ion beam (due to collimation inefficiency) not to be taken at face value: • X-sections for nuclear processes have estimated errors of ~±50% • 8.5 W/m heat load limit is only an average from early studies (Jeanneret et al.1996). Should really be considered on a magnet-to-magnet basis • hcoll~4% depends on impact parameter distribution on the scatterer (input assumption, difficult to predict..) • 12 min lifetime is another arbitrary number. Nominal ion beam with collision optics and standard collimator settings: Curtesy of Bellodi

11. Walter Scandale Crystal collimation Beam propagation Beam Core Crystal channeling Primary halo (p) Crystal Shower p p Sensitive equipment Absorber • Primary halo directly extracted! • Much less secondary and tertiary halos!? e ..but no enough data available to substantiate the idea…

12. Walter Scandale amorphous scatterer Crystal collimation: a smart approach for primary collimation • A bent crystal deflects halo particles toward a downstream absorber: • the selective and coherent scattering on atomic planes of an aligned Si-crystal may replace more efficiently • the random scattering process on single atoms of an amorphous scatterer. The hope is to get • Larger collimation efficiency • Larger gap of the secondary collimator --> reduced impedance

13. Walter Scandale RD 22: extraction of 120 GeV protons (SPS: 1990-95) The RD22 Collaboration, CERN DRDC 94-11 • Large channeling efficiency measured for the first time • Consistent with simulation expectation extended to high energy beams • Experimental proof of multi-turn effect (channeling after multi-traversals) • Definition of a reliable procedure to measure the channeling efficiency

14. Walter Scandale RD 22: extraction of ion (SPS: 1996-97) • Extraction experiments on bent crystals channelling were conducted at the SPS with ion beams in 1996-1997 (G.Arduini, W.Herr, J.Klem, L.Gatignon et al.) • Direct-type experiment on fully stripped Pb82+ ions at 400 GeV/c/u (external beamline) and 270 GeV/c/u (stored beam in ring with different excitation levels) • 60×18 mm crystal, bent over 50mm, 4mrad deflection, 3-points bend Theory: • Critical angle, dechannelling length and MS expected to depend on p/Z ratio ions should behave like p of equivalent momentum per charge • Nuclear interaction rate expected to be strongly decreased for channelled vs non-channelled ions • EMD should also decrease by a factor 10-100 • ….. however not confirmed by measurements ….

15. Walter Scandale RD 22: extraction of ions (SPS: 1996-97) • Single pass experiment– external beamline • Very good agreement with theoretical model, corroborates expectations • Ion channelling demonstrated for the first time, with efficiency ~10-14% • Multi-pass experiment – SPS ring • More complex problem with not so clear outcome • lack of knowledge on physics of nuclear interactions involved in multipass extraction • Narrower angular scan (suppressed contribution of multipass extraction?) • Lower deflection efficiencies (up to 10%) and bigger spread in values for different configurations • Open issues • EMD suppression not proved experimentally (neutron loss?) • Radiation damage to crystal not investigated(much lower limit expected than for p) • Multi-pass ion interactions not clear (Si~amorphous material if channelling conditions are not satisfied.. )

16. Walter Scandale At crystal Lambertson, crystal E853: extraction of 900 GeV protons (Tevatron: 1993-98) • Extracted significant beams from the Tevatron parasitic, kicked and RF stimulated • First ever luminosity-driven extraction • Highest energy channeling ever • Useful collimation studies • Extensive information on time-dependent behavior • Very robust

17. Walter Scandale Crystal collimation at RHIC STAR Background during crystal collimation • Indirect experiment (measure particles disappearance) with Au and p runs • Si crystal 5×1 mm with B=465 mrad located in interaction region matching section • Positioning not optimal (large beam divergence and  ≠ 0) • Crystal bends in the same plane where it scrapes  sensitivity to horiz. halo No clear interpretation of the results! • Measured ch. efficiency (~25%) doesn’t match theoretical predictions ( 56% with nominal machine optics). Better agreement and consistency when using measured beam divergence  need accurate knowledge of lattice functions. • Multipass physics and halo distribution models too simplistic? • Low channelling efficiency  collimation not successful & increased backgrounds !! Not conclusive & abandoned ! R.Fliller III, A.Drees, 2005 4 crystal scans with different scraper positions - xs

18. Walter Scandale Crystal collimation at FNAL Crystal Collimator in E0 replacing a Tungsten Target (2005) Crystal Tungsten scatterer Using the crystal, the secondary collimator E03 can remain further (-1 mm or so) from the beam and achieve almost a factor of 2 better result!

19. Walter Scandale The H8 line 4 m upstream Si det goniometer in 2006 bending magnets goniometer in 2007

20. Walter Scandale Goniometer with crystal holders S3 GC S5 vacuum vacuum B5 B6 vacuum p H S6 S2 S4 S1 Si microstrips (AMS) Si microstrips (AGILE) 70 m S2 B 6 Q 14 vacuum vacuum p 50 m 3-4 m The H8-RD22 apparatus 2006 Variant for 2007 Angular resolution

21. Walter Scandale beam Strip silicon crystals Crystals sizes: 0.9 x 70 x 3 mm3 and 0.5 x 70 x 3 mm3 Anticlastic bending Main bending • Strip Crystals have been fabricated in theSensors and Semiconductor Laboratory (U. of Ferrara) • Mechanical bending exploits anticlastic forces

22. Walter Scandale Quasi-mosaic silicon crystals Quasi-Mosaic Crystals fabricated in PNPI (Gatchina, Russia) • the mechanical bending of the crystal induces the bending of the atomic planes (initially flat and normal to large faces of plate) due to anisotropy •  depends on the choice of crystallographic plane and on the angle of n111 respect to the crystal face Quasi-mosaic bending Crystal plate sizes: ~ 1 x 30 x 55 mm3 O.I.Sumbaev (1957) critical angle for 400 GeV/c protons:qc ≈ 10 mrad Anticlastic bending R Main bending

23. Walter Scandale Crystals High precision goniometer Silicon detector Scintillator Goniometer Granite Block

24. Walter Scandale Detector upstream of the crystal (on the granite block): 1 double-sided silicon microstrip detector: Resolution ~ 10 mmin bending direction (X coordinate) Resolution ~ 30 mmin non-bending direction (Y coordinate) Active area ~ 7.0 x 2.8 cm2 Detector downstream of the crystal (on the granite block) : 1 BABY double-sided microstrip detectors (IRST): Resolution better than 10 mmin bending direction Resolution better than 20 mmin non-bending direction Active area ~ 1.9 x 1.9 cm2 DOWNSTREAM TELESCOPE (at 65 m from crystal location): 4 AMS LADDERS: Resolution ~ 10 mmin bending direction Resolution ~ 30 mmin non-bending direction Active area ~ 4 x 7 cm2 AMS Silicon Detectors Silicon thickness: 300 mm

25. Walter Scandale AGILE Silicon Detectors • Single-sided silicon strip detectors • Built by Agile (INFN/TC-01/006) • active area 9.5 x 9.5 cm2 • Spatial resolution: ~ 40 m at normal incidence (~ 30 m for tracks at 11°) • Silicon thickness: 410 mm • Upstream detector (before goniometer) • 2 silicon detectors at 90° (corresponds to 1 X-Y plane) • Downstream detector 1 (at 65 m from crystal location): • 4 X-Y silicon planes • Downstream detector 2 (at 65 m from crystal location): • 6 X-Y silicon planes interleaved with 300 m tungsten planes

26. Walter Scandale Gas Chamber and Scintillators • Gas Chamber • Parallel plate chamber • 0.6  12.8 mm2 active area • filled with Ar 70% + CO2 30% • 64 strips (pitch equal to 200 mm) • mounted on X-Y table • able to withstand rates up to 108 ppp • Scintillating detectors • Finger scintillators: 0.1  1  10 mm3 • Scintillating hodoscope: 16 strips with 2  4  30 mm3 read-out by MAPMT (fast beam monitoring) • Scintillator plates 100  100  4 mm3 used for triggering silicon detectors

27. Walter Scandale U  d Angular scan of a crystal (1) Predictions in 1985-’87 by A.M.Taratin and S.A.Vorobiev, and O.I. Sumbaev Theoretical explanation of channeling and volume reflection phenomena Channeled Reflected • Involved processes: • channeling • volume capture • de-channeling • volume reflection

28. Walter Scandale Angular scan of a crystal (2) Results of the angular scan with Strip Crystal measured volume reflection angle: ~ 10 mrad

29. Walter Scandale Angular scan of a crystal (3) measured volume reflection angle: ~ 10 mrad

30. Walter Scandale Scan of Quasi-Mosaic Crystal • Orientation (111) • Bending angle: ~ 80 rad • Crystal sizes: 30 x 58 x 0.84 mm3 measured volume reflection angle: ~ 10 mrad

31. Walter Scandale Double Reflection on Quasi-Mosaic Crystals (1) • Experimental setup: • exploited rotational stage for off-axis alignment of the first crystal (preliminary scan) • used upper linear stage for alignment of second crystal • many steps for finding perfect alignment conditions

32. Walter Scandale Double Reflection on Quasi-Mosaic Crystals (2) double reflection angle: ~ 20 mrad

33. Walter Scandale Refl2 Chan2 Refl1 Chan1 unperturbed Double Reflection on Quasi-Mosaic Crystals (3) Misaligned crystals -> two reflections angle: ~ 10 mrad

34. Walter Scandale Conclusive remarks • First observation of Volume Reflection Effect in bent silicon crystals with 400 GeV/c protons with efficiency close to unity • Measurement of volume reflection angle: ~ 10 mrad • First observation of Double Reflection using two crystals in series: combined reflection angle is ~ 20 mrad and efficiency close to 1 • Channeling and Volume Reflection phenomena studied with Strip and Quasi-Mosaic Silicon Crystals (different fabrication techniques) • Measurement of crystals with different crystalline planes orientations: (111) and (110) • Many thanks to • Efthymiopoulos, • L. Gatignon, • C. Rembser, • R. Maccaferri • SPS-OP team Many thanks for the financial support to • CARE-HHH • INTAS-CERN • INFN-CSN1 and INFN-NTA • CERN AB & AT departments

35. Walter Scandale Open issues • Crystal efficiency for channeling and volume reflection at both LHC injection (450 GeV) and top (7 TeV) energies. • Probability spectrum of proton deflections at 0.45 to 7 TeV for all physics processes down to a 10-5 level. • Damage limit of crystals for instantaneous shock beam impact at ~15 MJ/mm2. • Damage limit of crystals for integrated dose at ~5×1016 p/year at 7 TeV. • Handling of crystals during normal operation at high-power impact. • Requirements for alignment and operational set-up (goniometer conceptual design, tolerances, time, etc.). • ……. Ion specific concerns: • Si/ion interactions fairly understood for single pass channelling experiments.. what about multi-pass case? Crystal behaves like amorphous material for small impact parameters (surface effects) what happens to isotopes produced by nuclear interactions with the wrong rigidity? • What is the role played by nuclear/EM interactions in the case of volume reflection?

36. Walter Scandale Future plans • 7 weeks beam time requested in 2007 at the SPS • protons (H8 beam-line) at 400 GeV • electrons and/or positrons at 300 GeV • ions during dedicated MDs • Investigate edge-effect • Test of multi-strip crystals (Ferrara Sensor and Semiconductor Laboratory) to increase the angle of volume reflection • Test of germanium strip crystals and possibly zeolites • Upgrade of goniometric system with cradle for investigation of axial channeling • Upgrade and refurbishment of existing silicon microstrip detectors in order to increase spatial resolution • 0.1  1  10 mm3 • CARE-HHH workshop CC 07 22-23 March 2007 • Proposal of LARP to create a working group aiming at a crystal experiment in the Tevatron

37. Walter Scandale ALICE contribution • ALICE is supporting the effort of H8-RD22 in 2007, especially for the ion run • Crucial help expected in detecting fragmentation and EM dissociation down stream of the crystals in the next October run with ions