An efficient and robust collimation system is mandatory for any superconducting hadron collider, in particular for the LHC, which will store a beam of unprecedented high intensity and energy. The usage of highly efficient and short primary bent-crystal collimators might be a possibility for reaching nominal and ultimate LHC intensity. Over the last years, groups in Italy (Ferrara) and Russia (St. Petersburg) have developed crystal production methods, that considerably improve the crystal quality. These developments led, in turn, to a surprising increase in the channeling efficiency and to the recent observation of the âﾜvolume reflectionâ mechanism. The aim of the proposed experiment is the setup of a beam test facility, directing primary protons from the SPS onto a bent silicon crystal, and the quantitative study of single-pass efficiency for all involved processes. Final goal will be the extrapolation of important information on the feasibility of a crystal collimator for halo cleaning in the LHC. The experiment will be performed in the H8 beamline at the CERN SPS where a beam with very small divergence can be provided thus representing a unique facility for tests and characterization of crystals to be used for particle channeling studies

Ambrosi, Giovanni

Assmann, Ralph Wolfgang

Biino, Cristina

Chesnokov, Yuri

Dalpiaz, Pietro

Efthymiopoulos, Ilias

Fiorini, Massimiliano

Gatignon, Laurent

Guidi, Vincenzo

Ivanov, Yuri M

Santacesaria, Roberta

Scandale, Walter

Taratin, Alexander Mihailovich

Vomiero, Alberto

CERN Document Server

EUROPEAN ORGANIZATION FOR NUCLEAR RESEARCHLaboratory for Particle Physics(MAS)EXPERIMENTAL STUDY OF CRYSTAL CHANNELING AT CERN-SPSFOR BEAM-HALO CLEANINGM. Fiorini1, G. Ambrosi2, R. Assmann3, C. Biino4, Y. Chesnokov5, P. Dalpiaz1, I. Efthymiopoulos3,L. Gatignon3, V. Guidi1, Y. Ivanov6, R. Santacesaria7, W. Scandale3, A. Taratin8, A. Vomiero9*  Work supported by the European Community Research Integrated Activities - FP6 “Structuring the European    Research Area” programme (CARE, contract number RII3-CT-2003-506395), by INTAS 03-51-6155 and by    INFN project NTA-HCCC.1 University and INFN, Ferrara, Italy2 Sezione INFN, Perugia, Italy3 CERN, Geneva, Switzerland4 Sezione INFN, Torino, Italy5 IHEP Protvino, Moscow Region, Russia,6 PNPI Gatchina, Leningrad District, Russia,7 Sezione INFN, Roma, Italy8 JINR Dubna, Moscow Region, Russia,9 Laboratori Nazionali di Legnaro, Legnaro, ItalyCERN/AT 2006-9Presented at the Tenth European Particle Accelerator Conference (EPAC'06)26-30 June 2006, Edinburgh, UKGeneva, Switzerland 7 August 2006Departmental ReportAdministrative SecretariatAT DepartmentCERNCH - 1211 Geneva 23An efficient and robust collimation system is mandatory for any superconducting hadron collider, in particular forthe LHC, which will store a beam of unprecedented high intensity and energy. The usage of highly efficient andshort primary bent-crystal collimators might be a possibility for reaching nominal and ultimate LHC intensity.Over the last years, groups in Italy (Ferrara) and Russia (St. Petersburg) have developed crystal productionmethods, that considerably improve the crystal quality. These developments led, in turn, to a surprising increase inthe channeling efficiency and to the recent observation of the “volume reflection” mechanism. The aim of theproposed experiment is the setup of a beam test facility, directing primary protons from the SPS onto a bent siliconcrystal, and the quantitative study of single-pass efficiency for all involved processes. Final goal will be theextrapolation of important information on the feasibility of a crystal collimator for halo cleaning in the LHC.The experiment will be performed in the H8 beamline at the CERN SPS where a beam with very small divergencecan be provided thus representing a unique facility for tests and characterization of crystals to be used for particlechanneling studies.EXPERIMENTAL STUDY OF CRYSTAL CHANNELING AT CERN-SPSFOR BEAM-HALO CLEANINGM. Fiorini∗, P. Dalpiaz, V. Guidi, Ferrara University and INFN, 44100 Ferrara, Italy,R. Assmann, I. Efthymiopoulos, L. Gatignon, W. Scandale, CERN,CH-1211 Geneva 23, Switzerland, A. Taratin, JINR Dubna, Moscow Region, Russia,Y. Chesnokov, IHEP Protvino, Moscow Region, Russia, Y. Ivanov, PNPI Gatchina,Leningrad District, Russia, A. Vomiero, Laboratori Nazionali di Legnaro, 35020 Legnaro,Italy, C. Biino, Sezione INFN, 10125 Torino, Italy, G. Ambrosi, Sezione INFN,06123 Perugia, Italy, R. Santacesaria, Sezione INFN, 00185 Roma, ItalyAbstractAn efficient and robust collimation system is mandatoryfor any superconducting hadron collider, in particular forthe LHC, which will store a beam of unprecedented highintensity and energy. The usage of highly efficient andshort primary bent-crystal collimators might be a possibil-ity for reaching nominal and ultimate LHC intensity. Overthe last years, groups in Italy (Ferrara) and Russia (St. Pe-tersburg) have developed crystal production methods, thatconsiderably improve the crystal quality. These develop-ments led, in turn, to a surprising increase in the channel-ing efficiency and to the recent observation of the “volumereflection” mechanism.The aim of the proposed experiment is the setup of abeam test facility, directing primary protons from the SPSonto a bent silicon crystal, and the quantitative study ofsingle-pass efficiency for all involved processes. Final goalwill be the extrapolation of important information on thefeasibility of a crystal collimator for halo cleaning in theLHC.The experiment will be performed in the H8 beamline atthe CERN SPS where a beam with very small divergencecan be provided thus representing a unique facility for testsand characterization of crystals to be used for particle chan-neling studies.CRYSTAL CHANNELING AS AN OPTIONFOR LHC COLLIMATIONFor the new generation high intensity hadronic machinesas, for instance, LHC, halo collimation is a necessary con-dition to make the accelerator operational at the highestpossible luminosity and to prevent the damage of super-conductor magnets caused by spurious halo particles [1].Channeling of particles in crystals has been widely ex-perimented in circular machines and has shown record ef-ficiencies (up to 85%) for 70 GeV/c protons in extrac-tion mode at IHEP [2]. Aside particle channeling, a newphenomenon of deflection in crystals, called “volume re-flection”, has been experimentally observed during lastmonths [3]. This effect is closely related with channeling∗Corresponding author. E-mail address: fiorini@fe.infn.itin the basic physics, but is not characterized by channelingof particles among crystalline planes. However such phe-nomenon needs a systematic study to deepen its compre-hension and, ultimately, to understand whether such effectcould be employed in the physics of accelerators, in partic-ular for collimation in adronic machines.Silicon crystals have been employed since more than adecade to extract high intensity beams of relativistic parti-cles with more and more rising efficiencies by channelingeffect. Particles, channeled among lattice planes of a me-chanically bent crystal, do follow the curvature of the crys-tal, thus allowing their extraction out of the accelerator.Such crystal may be an optimal candidate for collima-tion: in fact particles trapped within the potential well ofatomic planes can be steered towards the desired direction,i.e. an aligned crystal substitutes disordered diffusion ofsingle-atom scattering in an amorphous target with coher-ent diffusion along the atomic planes. Thus a small andhighly efficient crystal could be employed as primary col-limator, which would make it possible to retract the sec-ondary collimator further from the beam and to make theLHC work at the highest luminosity, as a result of the con-sequent drop in the machine impedance.EXPERIMENTAL LAYOUTThe experiment consists of a single-particle tracking sys-tem for the particles passing through the crystal that willmake it possible to measure precisely the single pass ef-ficiency of all processes concerned with channeling and”volume reflection”.The secondary line allows the production of a beam char-acterized by an extremely low divergence (about 2 μrad),which is an exquisitely precise probe for the study of chan-neling. For this purpose, it is necessary to equip the beam-line with a suitable telescope for particle tracking and witha high-precision goniometric system necessary to the ex-periment.The experimentally determined deflection efficiency, forchanneling or volume reflection, is defined as the numberof fully deflected particles originating from a specific areaon the entrance face of the crystal, divided by the numberof particles incident on this area. Therefore it is possible1to determine the dependence of the efficiency on the pro-ton impact position on the crystal surface and to study effi-ciency around crystal edge with great detail.Goniometric systemThe experiment will use a goniometric system whose an-gular resolution is about 1 μrad and having 3 degrees offreedom, of which two are translationals and one rotational(Figure 1). The study of channeling phenomena requiresvery precise angular alignment of the crystal with respectto the proton beam. Since the proton beam we are going touse has an angular divergence of about 2 μrad and that thecritical angle for channeling of 400 GeV/c protons is about10 μrad, the most demanding issue of the goniometric sys-tem will be the repeatability of the alignment process (thatmust be of 1 μrad).Figure 1: Goniometer systemThe rotation stage, with 360◦ range around the verticalaxis, enables alignment of the crystal along the vertical axisallowing the channeling of the beam in the planes of thecrystal and the investigation of planar channeling condi-tions. Two linear stages (horizontal and vertical) will beused to place the crystal exactly inside the beam.The goniometer will host two mechanical holders forcrystals: with a 180◦ rotation and a linear movement it ispossible to select either one crystal or the other one, placingthem on the beam axis. This solution enables to study twodifferent crystals without interfering with the data takingand keeping the same experimental conditions.Two kinds of crystals have been fabricated for the ex-periment: the first one has been built following a stripconfiguration [4], while the second one exploits the quasi-mosaicity effect [5]. In order to fulfill the proposed objec-tives, crystals will be fabricated starting from high qualitysilicon, i.e. available as wafer with an extremely low anglebetween the crystal nominal direction and the crystal sur-face direction (“miscut angle”). Starting from these wafers,crystals specifically designed to optimize 400 GeV/c pro-tons channeling will be realized. In particular, the de-flection angle foreseen for best halo collimation in LHCwill be considered, that is an angle of about 100 μrad.Corresponding to such an angle, simulations by specificcodes have produced an optimal thickness of 3 mm for thecrystal crossed by particles. The crystals have been char-acterized, in addition, in terms of surface morphologicalstructure with both XRD at PNPI and through RutherfordBack-Scattering (RBS) spectroscopy in channeling modeat LNL [6].Beamline layoutIn order to be able to measure channeling efficiency ofprotons on mechanically bent silicon crystals and to resolvethe beam component that experienced ”volume reflection”,it is necessary to arrange a tracking system with excellentspatial resolution and good time resolution.The experiment will make use of a primary proton beamwith 400 GeV/c momentum, 5 mm diameter in the hor-izontal plane and 4 mm in the vertical plane and with avery small (2 μrad) divergence. The primary beam in-tensity is very high (20 × 1011 ppp), but can be reduceddown to 104 − 105 ppp without affecting significantly thebeam divergence. This intensity is relatively low and al-lows to track every single beam particle and therefore tocompletely reconstruct an event.The experimental scheme is illustrated in Figure 2. Thecrystals will be mounted on mechanical holders, fixed onthe goniometer, that will be moved by a remote controlsystem. A laser system is necessary to define the relativeposition of the goniometer in measurement site, essentialreference to define the absolute position through linear andangular positions. Crystal alignment with respect to thebeam will be carried out through an angular scanning, pro-ducing a crystal rotation around a vertical axis. Thereforeit will be possible to identify channeling conditions for thecrystal, rotating it until a peak in the protons distributionnear channeling angle is observed. From an experimentalpoint of view it will be possible to separate the differentbeam components at a distance of about 40 m and 65 mdownstream of the crystal.For a crystal bending angle of 100 μrad, we expect thatthe channelled component of the beam, incident on thecrystal, is detected at a distance of 4 mm (at 40 m from thecrystal) with respect to the component of the beam whichhas just undergone multiple scattering. The divergenceof the channeled component in the crystal is determinedby critical angle and therefore is of the order of 10 μrad.Considering recent results and dedicated simulations, weexpect that the component of the beam which undergoesvolume reflection is deviated of an angle of about 10-20μrad in the opposite direction of the channeled one. On thecontrary there is no experimental information on the diver-gence of such component, but we expect it to be of the orderof 10 μrad. The basic idea of the experiment is to track ev-ery single particle that crosses the crystal and to determinesingle pass efficiencies for the various processes.Particle trackingThe tracking system will be made of two different sili-con microstrip detectors having excellent spatial resolution.2Figure 2: Experimental layoutThose detectors were designed for space applications andare best suited for this experiment in virtue of their reso-lution and thickness. In particular AMS-type [7, 8] doublesided and AGILE-type [9] single sided silicon microstripdetectors will be used in different locations along the beamdirection.The first measurement stations will be placed upstreamof the crystal and next to it, in order to define proton im-pact point on crystal surface. A second station will beplaced, following protons trajectory, at about 40 m fromcrystal, while the last one will be installed at 65 m fromthe goniometer. These last stations will define, with greatprecision, the trajectory of the particle coming out fromthe crystal and will allow to distinguish the different beamcomponents. In addition, the limited material budget of thedetectors (300-400 μm along the beam direction for siliconstrips, 1-2 mm for scintillators) allows to preserve the beamdivergence.A trigger system, based on scintillation counters (S1-S4), is necessary in order to remove background and notinteresting events. Trigger signal will be made up, in thesimplest configuration, of a coincidence between a down-stream counter and one upstream of the crystal. In additiona hodoscope made up of scintillating strips (H) will be con-structed, which will be employed to give quick informationabout crystal alignment and moreover to select events con-sidering their particular topology. Crystal positioning sys-tem inside the beam will be made up of a couple of scin-tillators (S1, S2), having the same sizes of the crystal andfixed on a system integral with itself, with the possibility tobe withdrawn during data taking.CONCLUSIONSMain features of the proposed experiment are the use ofnew generation crystals and the tracking of single particlesin an external beamline at the SPS (CERN). Goals of theexperiment are the determination of single-pass channelingand volume reflection efficiency. A two weeks data takingperiod with protons is scheduled for September 2006 in theH8 beamline at the SPS.ACKNOWLEDGMENTSWe acknowledge support by INFN NTA-HCCC andCSN I, INTAS-CERN 03-52-6155 and MIUR 2004083253projects.REFERENCES[1] V. M. Biryukov, V. N. Chepegin, Y. A. Chesnokov, V. Guidiand W. Scandale, Nucl. Instrum. Meth. B 234 (2005) 23.[2] A.G. Afonin et al., “Advances in the investigation of the ex-traction of a proton beam from the U-70 accelerator with theaid of bent single crystals”, Journal of Experimental and The-oretical Physics Letters 74 (2001) 55-58[3] W. Scandale et al., “First Observation of Proton Reflectionfrom Bent Crystals”, Poster, these Proceedings.[4] A. G. Afonin et al., Phys. Rev. Lett. 87 (2001) 094802.[5] Yu. M. Ivanov, A. A. Petrunin and V. V. Skorobogatov, “Ob-servation of the elastic quasi-mosaicity effect in bent siliconsingle crystals”, JETP Letters, Vol. 81, No. 3, 2005[6] V. Guidi et al., “Characterization of Crystals for Steeringof Protons through Channelling in Hadronic Accelerators”,Poster, these Proceedings.[7] J. Alcaraz et al.,“A Silicon Microstrip Tracker in Space: Experience with theAMS Silicon Tracker on STS–91”Il Nuovo Cimento 112A (1999), 1325.[8] B. Alpat et al.,“The AMS Silicon Tracker Readout: Performance Resultswith Minimum Ionizing Particles”Nuclear Instruments and Methods A439 (2000) 53.[9] G. Barbiellini et al., Nucl. Instrum. Meth. A 490 (2002) 146.3

Experimental Study of Crystal Channelling at CERN-SPS for Beam-Halo Cleaning

Experimental Study of Crystal Channelling at CERN-SPS for Beam-Halo Cleaning

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