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HiRadMat Summary of Phase-I and plans for Phase-II commissioning J. Blanco, N. Conan, V. Kain, K. Cornelis, B. Goddard, C. Hessler, M. Meddahi, C. Theis,

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Presentation on theme: "HiRadMat Summary of Phase-I and plans for Phase-II commissioning J. Blanco, N. Conan, V. Kain, K. Cornelis, B. Goddard, C. Hessler, M. Meddahi, C. Theis,"— Presentation transcript:

1 HiRadMat Summary of Phase-I and plans for Phase-II commissioning J. Blanco, N. Conan, V. Kain, K. Cornelis, B. Goddard, C. Hessler, M. Meddahi, C. Theis, P. Vojtyla, J. Wenninger On behalf of the HiRadMat Primary beam line working group All details published in EDMS #1154385 HRM-CERN-ATS-Note-2011-55

2 2 HiRadMat Facility at CERN

3 3 Beam Line Geometry Beam C. Magnier25 m Experimental area TI 2 TT60 TT66

4 4 Beam Line Layout Beam Exp. areaSPS extraction point End of common part with TT60 MBS switching magnets MBBQTL 50 m MBSMBBQTL

5 5 Layout of Experimental Area  Flexible optics to provide beam radii of  = 0.1mm to 2.0 mm at the focal points.  Focal point longitudinal location continuously variable between positions 1 and 3.  Predefined optics for 3 focal points and 6 beam sizes. BTV Large test object Small test objects

6 6 Equipment Inventory  25 magnets installed (+ de and re-installation of 4 TI 2 magnets)  13 power converters installed (+1 new for TT60)  17 beam instrumentation elements installed  ~200 m of new vacuum system installed (+ adaption of TI 2 vacuum system)  ~460 new cables with a total length of 4000 m installed (+ dismantling of 300 old cables) →All was done during 4-day technical stops, the Xmas stop and short accesses between LHC injections. Thanks to all equipment groups!

7 7 Beam Parameters ParameterProtonsIons Beam energy440 [GeV]173.5 [AGeV] Bunch intensity3×10 9 to 1.7×10 11 [protons] (current multi bunch 1.2 ×10 11 ) 3×10 7 to 7×10 7 [ions] Max. pulse intensity4.9×10 13 [protons]3.64×10 9 [ions] Number of bunches1 to 288 (current: 144)52 Bunch spacing25 [ns] (current: 50 ns)100 [ns] RMS bunch length11.24 [cm] Pulse length7.2 [μs]5.2 [μs] Number of pulses per cycle11 Min. cycle length21.6 [s]13.2 [s] Transverse norm. emittance (1σ)2 to 4 [μm]1.4 [μm] More efficient to get your total number of protons by using the proton beam which is set-up for the on-going LHC operation

8 8 Beam Optics (1)  Example of a typical beam with  =0.5 mm and focal point at position 1: C.Hessler

9 9 Beam Optics (2)  Example of a typical beam with  =0.1 mm and focal point at position 1: C.Hessler

10 10 Beam Optics (3)  Example of a typical beam with  =2.0 mm and focal point at position 1: C.Hessler

11 11 Trajectory Correction and Orthogonal Steering  Orthogonal steering on target +/- 4 mm independently in both planes. If larger range is needed, the test object will be moved.  Max. accuracy of angle: ~0.05 mrad  = 0.5 mm Example: C.Hessler

12 12 Beam Instrumentation InstrumentTypeQuantity BPM (dual plane)LEP buttons6 BPKG* (dual plane)CNGS1 BTVILHC3 BCTFICNGS1 BLMLHC6 * operated in air BPMBLMBTVIBCTFI L. Jensen and team

13 13 Interlock (1)  Beam interlock controller: Extension of existing interlock system to handle new interlock signals from HiRadMat facility.  New energy flag E_440 for HiRadMat.  FMCMs for main bending magnets.  TBSE in TI 2 to ensure accessibility of TI 2 / LHC during HiRadMat operation.  Interlock system of LSS6 extraction has now exactly the same layout than in LSS4 where CNGS and LHC beams coexist. This system has proven to be very reliable. B. Puccio, M. Zerlauth, V. Kain, J. Wenninger

14 14 Interlock (2) Comparison extraction layout LSS6 (TI 2, HiRadMat) versus LSS4 (TI 8, CNGS): B. Puccio, M. Zerlauth, V. Kain, J. Wenninger

15 15 Interlock (3) System layout: HiRadMat interlock application: B. Puccio, M. Zerlauth, V. Kain, J. Wenninger

16 16 Control Applications (1)  All standard equipment → extension of existing applications:  Steering, logging: Extension of YASP  BTVs, BLMs, BCT: Extension of the corresponding application  New dedicated application for an easy change of the HiRadMat beam line optics: V. Kain

17 17 Control Applications (2)  New dedicated application for requesting beam for HiRadMat. Each pulse sent to HiRadMat must be requested with this application (= 1 pulse per click).  Use will be restricted to authorised operators only (using RBAC). V. Kain Click here to request beam

18 18 Control Applications (3)  The following beam line equipment is logged in TIMBER:  BTVs (also in SDDS)  BLMs  BPMs  BCTFI  Power converter currents  Beam interlocks V. Kain

19 19 Dry Run Results (1)  All magnets powered and polarity checked.  Applications for beam instrumentation have been successfully checked (BTV, BCTFI, BLM). V. Kain, J. Wenninger, J. Blanco BTV applicationBCTFI application

20 20 Dry Run Results (2)  YASP acquires data for TT66.  Logging has been successfully checked.  Interlock successfully tested.  Application for beam optics change successfully tested.  Beam request application successfully tested. V. Kain, J. Wenninger, J. Blanco YASPTIMBER (Logging)

21 21 Extraction Tests on TT60 TED  First extraction of probe bunches with HiRadMat cycle onto TT60 TED (= far upstream the start of TT66): V. Kain, J. Wenninger, J. Blanco

22 22 Beam Commissioning Plan (1)  Different kind of beams to be used:  LHC probe “pilot”: ~8×10 9 p/bunch  LHC2 “nominal”: up to ~1.3×10 11 p/bunch  1 batch of 12 bunches with 50 ns bunch spacing  2 batches of 12 bunches  1 batch of 36 bunches  2 batches of 36 bunches → max. 72 b. per extraction  Beam budget estimate:  1 st period:  24 h of pilot bunches  total # of protons: ~10 13  2 nd period:  Pre-checks with pilot beam  4 h of multi-bunches, mostly with 1 batch of 12 bunches  total # of protons: ~2×10 14

23 23 Beam Commissioning Plan (2) TestBeam type# bunchesBunch intensity # shotsMax. total intensity Time Send beam onto TED.610321 Test of the extraction from SPS LHC probe110 5010 12 2h Sending beam “LHC Probe” to HiRadMat Beam line bare trajectory and steering LHC probe1~8×10 9 90~7.2×10 11 2h Beam instrumentation (incl. calibration, check response, checks of corrector and pickups) LHC probe1~8×10 9 180~14.4×10 11 4h Controls, loggingLHC probe1~8×10 9 30~2.4×10 11 0.5 h Steering on targetLHC probe1~8×10 9 60~4.8×10 11 1h Interlocking tests (interlock limits) LHC probe1~8×10 9 30~2.4×10 11 0.5 h Aperture checks (knobs needed, to be done with 1 reference optics) LHC probe1~8×10 9 240~19×10 11 5h Beam parameters checksLHC probe1~8×10 9 90~7.2×10 11 2h Beam size and focal point position adjustment LHC probe1~8×10 9 180~14.4×10 11 4h Position/intensity stabilityLHC probe1~8×10 9 60~4.8×10 11 1h Change of beam line optics + repetition of some tests LHC probe1~8×10 9 180~14.4×10 11 4h Sending beam “LHC2 nominal” to HiRadMat Re-check trajectoryLHC2 nominal 12~1.3×10 11 10~1.6×10 13 0.5h Check beam instrumentation (BTV Ti screens, readings for high intensities, etc.) LHC2 nominal 12~1.3×10 11 20~3.2×10 13 1h Beam parameters checksLHC2 nominal 12~1.3×10 11 20~3.2×10 13 1h Increase intensity in steps and check consistency of nominal beam with probe beam LHC2 nominal 24~1.3×10 11 5~1.6×10 13 0.5 h LHC2 nominal 36~1.3×10 11 5~2.3×10 13 0.5 h LHC2 nominal 72~1.3×10 11 5~4.7×10 13 0.5 h

24 24 Beam Commissioning Plan (3)  Sending beam “LHC Probe” to HiRadMat. Tests to be carried out:  Beam line bare trajectory and steering  Beam instrumentation (incl. calibration, check response, checks of corrector and pickups)  Controls, logging  Steering on target  Interlocking tests (interlock limits)  Aperture checks (knobs needed, to be done with 1 reference optics)  Beam parameters checks  Beam size and focal point position adjustment  Position/intensity stability  Change of beam line optics + repetition of some tests  Some high intensity shots to check the consistency with the nominal beam intensity.

25 First HiRadMat proton beam extracted from the SPS to the HiRadMat beam dump Bare trajectories

26 Trajectory after energy matching and trajectory excursion corrections Beam on the 2 of the HiRadMat primary beam line screens

27 Kick response measurements: correct polarity sign of BPM, Correctors and no phase advance / optics errors

28 Beam line aperture checks

29 Orthogonal steering onto the future test stand location 29 Steering of the beam on the last BTV screen independently in both planes within the range +/- 4 mm Example trajectory for the case that the beam was steered to +4 mm in the vertical plane

30 Multiple Optics changes – example of F1 30 Difference of the trajectory after changing the optics from F1-0_50mm-0_50mm to F1-0_20mm-0_20mm New steering for F1-0_20mm-0_20mm optics

31 RP monitoring 31 Readings (Sv/h) of the residual dose rate monitor PMIHR05 installed next to the dump in the HiRadMat experimental area. It can be seen that with the exception of the spikes due to the prompt radiation the residual dose rate before and after the commissioning remained unchanged at ~80 uSv/h - None of the radiation monitors raised any concern and the first commissioning phase of HiRadMat can be considered as a success also from the radiation protection point of view. N. Conan, C. Theis, P. Vojtyla

32 Outcomes  Beam commissioning with pilot intensity allowed to check the correct functioning of the primary beam line equipment, optics and beam quality  High intensity beam commissioning scheduled as mid-August (week 33)  Thanks again to all equipment groups for their work and assistance through the whole project lifetime and to the SPS Operation Team 32

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