1 October 2007Reflection on bent crystals W. Scandale 1/24 OBSERVATION OF PROTON REFLECTION ON BENT SILICON CRYSTALS AT THE CERN-SPS Walter Scandale CERN.

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1 October 2007Reflection on bent crystals W. Scandale 1/24 OBSERVATION OF PROTON REFLECTION ON BENT SILICON CRYSTALS AT THE CERN-SPS Walter Scandale CERN For the H8-RD22 collaboration (CERN, FNAL, INFN, IHEP, JINR, PNPI) BEAM September 2007

1 October 2007Reflection on bent crystals W. Scandale 2/24 Outlook  Why using crystals in hadron colliders  The H8-RD22 experiment at CERN  Experimental layout  High precision goniometric system  Tracking detectors  Silicon crystals(Strip and Quasi-Mosaic Crystals)  Interaction with 400 Gev proton beam  Observation of volume reflection and channeling  Deflection angles  Single-pass efficiency  Multi-crystal volume reflection  Axial channeling  Conclusions

1 October 2007Reflection on bent crystals W. Scandale 3/24 Secondary halo p p e  Primary collimator (scatterer) Beam Core Shower Beam propagation Impact parameter ≤ 1  m Sensitive equipment Primary halo (p) e  Shower p Tertiary halo Secondary collimator (massive absorber) Two stage collimation

1 October 2007Reflection on bent crystals W. Scandale 4/24 p Beam propagation Sensitive equipment Primary halo (p) Absorber  Primary halo directly extracted!  Much less secondary and tertiary halos  Larger gap in the secondary collimators e  Shower Crystal Crystal collimation Beam Core …but not enough data available yet to substantiate the idea… E. Tsyganov & A. Taratin (1991)

1 October 2007Reflection on bent crystals W. Scandale 5/24 Particle-crystal interaction Possible processes:  multiple scattering  channeling  volume capture  de-channeling  volume reflection d U Volume reflection Prediction in 1985-’87 by A.M.Taratin and S.A.Vorobiev, First observations in 2006 (IHEP - PNPI - CERN)

1 October 2007Reflection on bent crystals W. Scandale 6/24 The basic H8RD22 apparatus S1 Si microstrips (AGILE) S3 GC S5 vacuum Si microstrips (AMS) p S2 70 m H S4 S6 B5 B6 Goniometer & crystal holders Si microstrips (AGILE) hodoscope Gas chamber Scintillation counters (trigger) Main functionality:  Identify direction and slope of the incoming and out-going tracks  Identify beam profiles  Detect incoming and out-going particle flux 400 GeV primary proton beam

1 October 2007Reflection on bent crystals W. Scandale 7/24 AMS AGILE pitch 110  m,  =14  mpitch 242  m,  =22  m Si microstrips Built at INFN - PerugiaBuilt at INFN - Como & Trieste

1 October 2007Reflection on bent crystals W. Scandale 8/24  Two motors for translations 2 μ m repeatability 102 mm range (upper stage) 52 mm range (lower stage) Goniometer  One motor for H-rotations 360° range 1.5 μ rad precision 1 μ rad repeatability Assembled at INFN - Legnaro  One motor for V-rotations (added later) > ± 10° range 1.5 μ rad precision 1 μ rad repeatability

1 October 2007Reflection on bent crystals W. Scandale 9/24 The main curvature due to external forces induces the anticlastic curvature seen by the beam Crystal size: 0.9 x 70 x 3 mm 3 Strip crystals Built at IHEP - Protvino and at INFN - Ferrara Main radius of curvature Radius of anticlastic curvature

1 October 2007Reflection on bent crystals W. Scandale 10/24 Quasi-Mosaic effect (Sumbaev, 1957) The crystal is cut parallel to the planes (111). An external force induce the main curvature. The anticlastic effect produces a secondary curvature The anisotropy of the elastic tensor induces a curvature of the crystal planes parallel to the small face. Beam direction Quasimosaic crystals Built at PNPI - Gatchina Crystal size: 0.7 x 30 x 30 mm 3

1 October 2007Reflection on bent crystals W. Scandale 11/24 Data taking  Pre-alignment of the crystal respect to the beam line using optical methods  Fast alignment of the crystal to the beam direction through the hodoscope (pitch 2 mm): the channeling peak is well visible at about 1 cm from the non-deflected beam  Fast angular scan using the gas chamber (pitch 200  m) and a high intensity beam (10 8 proton per SPS pulse): the reflection region is well visible.  High statistics scan with the Si microstrip, in the range predefined by the fast angular scan (10 4 protons per SPS pulse)

1 October 2007Reflection on bent crystals W. Scandale 12/24 Rotation angle (µrad ) Angular profile (µrad) 1 -“amorphous” orientation 2 -channeling 3 -de-channeling 4 -volume capture 5 -volume reflection Angular beam profile as a function of the crystal orientation The particle density decreases from red to blue The angular profile is the change of beam direction induced by the crystal The rotation angle is angle of the crystal respect to beam direction

Angular profile (µrad) Rotation angle (µrad ) Angular profile µrad Amorphous counts

Angular profile (µrad) Rotation angle (µrad ) Angular profile µrad Channeling counts

Angular profile (µrad) Rotation angle (µrad ) Angular profile µrad VolumeReflection counts

1 October 2007Reflection on bent crystals W. Scandale 16/24 Angular profile µrad channelingamorphous reflected Deflection  Identify channeling, reflection and amorphous peaks of the angular profile distribution  Compute the angular shift -> deflections  (underlying hypothesis: the incoming beam follows a stable direction)  channeling  reflection

1 October 2007Reflection on bent crystals W. Scandale 17/24 Efficiency  Integral of the events within ±3  around amorphous, channeling and reflected peaks  Normalize the integrals to the incoming flux  Ratios of channeling or deflection over amorphous normalized peak integrals -> efficiencies  (underlying hypothesis: the incoming beam flux is stable) Example of efficiency estimate 49.9% Channeling 95.5% 93.8%Volume reflection “amorphous” P

1 October 2007Reflection on bent crystals W. Scandale 18/24 QM2 quasimosaic crystal  (reflection)= 98.2 %  (channeling)= 52.7 %  channeling = 73  rad  reflection = 12  rad ST4 strip crystal  (reflection)= 98.2 %  (channeling)= 51.2 %  channeling = 163  rad  reflection = 14  rad Typical results

1 October 2007Reflection on bent crystals W. Scandale 19/24 double reflection angle: ~ 20  rad Double Reflection on Quasi-Mosaic Crystals Experimental procedure:  alignment of the first crystal though the H-rotational stage  alignment of second crystal though the upper linear stage (anticlastic bend)  many steps for finding optimal alignment

1 October 2007Reflection on bent crystals W. Scandale 20/24 5 heads multi-crystal crystal (PNPI) p Multi Reflection on Quasi-Mosaic Crystals (1)

1 October 2007Reflection on bent crystals W. Scandale 21/24 High statistics Best alignment  Volume reflection angle 53  rad  Efficiency  90 % Steps to align the five crystals Multi Reflection on Quasi-Mosaic Crystals (2)

1 October 2007Reflection on bent crystals W. Scandale 22/24  Planar-to-axial channeling transition  Variation of VR effect with the vertical angle Channeling from secondary crystal planes Vertical beam profiles Cradle alignment Axial channeling in a single crystal In axial channeling mode the crystal produces an angular spread of ±50  rad

1 October 2007Reflection on bent crystals W. Scandale 23/24 Conclusion  High efficient reflection (and channeling) observed in single pass interaction of high-energy protons with bent crystals (0.5 to 10 mm long)  Single reflection on a Si bent crystal deflects > 98 % of the incoming 400 Gev p beam by an angle 12÷14  rad  Multi-reflections on a sequence of aligned crystals to enhance the reflection angle successfully tested with two and five consecutive crystals.  Axial channeling observed (scattering enhancement) Very promising results for application in crystal collimation

1 October 2007Reflection on bent crystals W. Scandale 24/24 Acknowledgments We acknowledge partial support by CERN AB & AT The European Community-Research Infrastructure Activity under the FP6 “Structuring the European Research Area” program (CARE, contract number RII3-CT ), the INTAS program The MIUR project, The Russian Foundation for Basic Research grant , The Council of the President of the Russian Federation grant NSh , The Program "Physics of Elementary Particles and Fundamental Nuclear Physics" of Russian Academy of Sciences. INFN: NTA program

1 October 2007Reflection on bent crystals W. Scandale 25/24 Particle-crystal interaction Possible processes:  multiple scattering  channeling  volume capture  de-channeling  volume reflection d U Volume reflection Prediction in 1985-’87 by A.M.Taratin and S.A.Vorobiev, First observation 2006 (IHEP - PNPI - CERN)

1 October 2007Reflection on bent crystals W. Scandale 26/24 The RD22 Collaboration, CERN DRDC  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 RD 22: extraction of 120 GeV protons (SPS: )

1 October 2007Reflection on bent crystals W. Scandale 27/24 RD 22: extraction of ions (SPS: )  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.. )

1 October 2007Reflection on bent crystals W. Scandale 28/24 At crystal Lambertson, crystal E853: extraction of 900 GeV protons (Tevatron: )  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

1 October 2007Reflection on bent crystals W. Scandale 29/24 Crystal collimation at RHIC  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 !! R.Fliller III, A.Drees, crystal scans with different scraper positions - x s STAR Background during crystal collimation Not conclusive & abandoned !

1 October 2007Reflection on bent crystals W. Scandale 30/24 Crystal Collimator in E0 replacing a Tungsten Target (2005) Crystal collimation at FNAL 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! Tungsten scatterer Crystal