Challenges and Progress on the SuperBeam Horn Design NuFact 08 Valencia-Spain, June 30 - July 5 2008 Marcos DRACOS IN2P3/CNRS Strasbourg 30 June 2008 M.
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Challenges and Progress on the SuperBeam Horn Design NuFact 08 Valencia-Spain, June 30 - July 5 2008 Marcos DRACOS IN2P3/CNRS Strasbourg 30 June 2008 M. Dracos, NuFact08 1 Super-Beam Studies in Europe • Super Proton Driver at CERN (SPL) • Target and collector integration • Hadron Collector • Pulser • Conclusion 30 June 2008 M. Dracos, NuFact08 2 Conventional Neutrino Beams proton beam hadrons p target 30 June 2008 p Decay tunnel hadron collector (focusing) M. Dracos, NuFact08 physics n Detector 3 SPL Super-Beam Project H- linac 2.2, 3.5 or 5 GeV, 4 MW Accumulator ring + bunch compressor p proton driver Magnetic horn capture (collector) p Target hadrons n, m decay tunnel ~300 MeV nm beam to far detector to be studied in EUROn WP2 30 June 2008 M. Dracos, NuFact08 4 Super Proton Linac at CERN SPL (http://doc.cern.ch/yellowrep/2006/2006-006/full_document.pdf) 30 June 2008 M. Dracos, NuFact08 5 SPL (CDR2) main characteristics Ion species H- Kinetic energy 3.5 GeV Mean current during the pulse 40 mA Mean beam power 4 MW Pulse repetition rate 50 Hz Pulse duration 0.57 ms Bunch frequency 352.2 MHz Duty cycle during the pulse 62 (5/8) % rms transverse emittances 0.4 p mm mrad Longitudinal rms emittance 0.3 p deg MeV Length 430 m butch compressor to go down to 3.2 ms (important parameter for hadron collector pulsing system) (possible energy upgrade to 5 GeV could be the subject of a 3rd CDR) 30 June 2008 M. Dracos, NuFact08 6 Proton Target • 300-1000 J cm-3/pulse • Severe problems from : sudden heating, stress, activation • Safety issues ! • Baseline for Super-Beam is solid target, mercury is optional (baseline for NF) – Extremely difficult problem : need to pursue two approaches : • Liquid metal target (Merit experiment) • Solid target (extensive R/D program at CCLRC and BNL) • Envisage alternative solutions 30 June 2008 M. Dracos, NuFact08 7 Proposed collection system proton beam horn 300 kA 8.5° 3.7 cm 4 cm target 40 cm 16.6 cm 80 cm taking into account the proton energy and collection efficiency, the target must be inside the horn 30 June 2008 M. Dracos, NuFact08 8 Proton Target some ideas CC target Horn Proposed rotating tantalum target ring (realistic?) Helium cooling of target He OUT He IN fluidised jet of particles cooling is a main issue… 30 June 2008 M. Dracos, NuFact08 Liquid Mercury (MERIT) Work at BNL and RAL Experience on T2K target (750 kW) very useful 9 Hadron production Particles coming out of the target 2.2 GeV protons pT distribution not the same for all targets the choice of the target could influence the hadron collection system (horn shape) pT 30 June 2008 M. Dracos, NuFact08 From now on Hg will be considered 10 Hadron production uncertainties 2.2 GeV protons p+ momentum disagreement between models (Monte Carlo production, interaction and transport codes) more development is needed (simulation, measurements) 30 June 2008 M. Dracos, NuFact08 11 Proton Energy and Pion Spectra • pions per proton on target. • Kinetic energy spectrum – 2.2 GeV: interesting region for SPL SB Ekine (GeV) 1GeV 2GeV • <Ek>=300MeV – 3.5 GeV: cos q • <Ek>=378MeV hadrons boosted forward -1 30 June 2008 0 1 M. Dracos, NuFact08 12 Proposed design for SPL for pions coming out of the target 500 < pp < 700 MeV/c p+ angle p+ momentum horn region for a Hg target, 30 cm length, 15 mm (x1016/sec) relatively better collection when pproton 30 June 2008 M. Dracos, NuFact08 the target must be inside the horn 13 Horn geometry • • 2.2 GeV proton beam : – <pp> = 492 MeV/c – <qp> = 55° I = 300 kAmp r(m) – <pp> = 405 MeV/c – <qp> = 60° r(m) 3.5 GeV proton beam : B~1/r I = 300 kAmp B~1/r target 30 cm 30 June 2008 B must be 0 4 cm 4 cm B must be 0 z(m) M. Dracos, NuFact08 target 30 cm z(m) 14 Proposed design for SPL 600 kA proton beam Hg target reflector horn 300 kA 3.7 cm 8.5° 4 cm 12.9° 16.6 cm 20.3 cm 4 cm 40 cm 80 cm 70 cm very high current inducing severe problems 30 June 2008 M. Dracos, NuFact08 15 Focusing Power p- transverse momentum p+ transverse momentum (2.2 GeV option) p- are deflected 20% more p+ with reflector 30 June 2008 M. Dracos, NuFact08 16 Present Collectors In operation (120 GeV) In operation (8 GeV) completed (12 GeV) CERN horn prototype for SPL Super-Beam (3.5 GeV) In operation (400 GeV) MiniBooNE 30 June 2008 NUMI M. Dracos, NuFact08 CNGS K2K 17 Decay Tunnel Flux vs decay tunnel length (2.2 GeV option) short decay tunnel 30 June 2008 M. Dracos, NuFact08 18 More about previous studies •S. Gilardoni: Horn for Neutrino Factory and comparison with a solenoid •http://doc.cern.ch/archive/electronic/cern/preprints/thesis/thesis-2004-046.pdf •http://newbeams.in2p3.fr/talks/gilardoni.ppt •A. Cazes: Horn for SPL •http://tel.ccsd.cnrs.fr/tel-00008775/en/ •http://slap.web.cern.ch/slap/NuFact/NuFact/nf142.pdf •http://slap.web.cern.ch/slap/NuFact/NuFact/nf-138.pdf 30 June 2008 M. Dracos, NuFact08 19 Main Technical Challenges • • • • • • • • Horn : as thin as possible (3 mm) to minimize energy deposition, Longevity in a high power beam (currently estimated to be 6 weeks!), 50 Hz (vs a few Hz up to now), Large electromagnetic wave, thermo-mechanical stress, vibrations, fatigue, radiation damage, Currents: 300 kA (horn) and 600 kA (reflector) – design of a high current pulsed power supply (300 kA/100 μs/50 Hz), cooling system in order to maintain the integrity of the horn despite of the heat amount generated by the energy deposition of the secondary particles provided by the impact of the primary proton beam onto the target, definition of the radiation tolerance, integration of the target. 30 June 2008 M. Dracos, NuFact08 20 CERN horn prototype cooling system Current of 300 kA p Protons To decay channel B=0 Hg Target B1/R initial design satisfying both, neutrino factory and super-beam 30 June 2008 M. Dracos, NuFact08 21 Energy deposition in the conductors MARS 48.2 kW 67kW 14.9kW 78.7kW +8kW from Joule effect 4MW, 2.2GeV proton beam (1MeV = 1.82 kW) 30 June 2008 M. Dracos, NuFact08 22 P (kW) Localization of the energy deposition target z (cm) z (cm) power deposited in the inner conductor as a function of z 30 June 2008 z position of the particles coming out of the target M. Dracos, NuFact08 23 Horn prototype • For the horn skin AA 6082-T6 / (AlMgSi1) is an acceptable compromise between the 4 main characteristics: – Mechanical properties – Welding abilities – Electrical properties – Resistance to corrosion – Same for CNGS …but Al not compatible with Mercury! •tests done with: 30 kA and 1 Hz, pulse 100 ms long •new tests to be Electrical and water connections done with 50 Hz 30 June 2008 M. Dracos, NuFact08 24 Power Supply for horn pulsing (major issue) values considered by CERN 30 June 2008 M. Dracos, NuFact08 25 3 Solutions proposed by ABB schematic versions at the capacitors ends option 1 at the capacitors ends option 2 Switching device in the charge Diode Load option 3 30 June 2008 ms M. Dracos, NuFact08 26 Pulser simulation parameters • magnetic field with electrical excitation (pulses 100 μs, 50 Hz) • induced current distributions • magnetic forces • temperature and expansion distributions • mechanical constraints and deformations (static+ dynamical), vibration modes • non-linear magnetic and thermal effects in the calculation of mechanical constraints • fatigue (and constraints from radiations if any) studies are needed to make the right choice, increase the system lifetime, reduce the cost 30 June 2008 M. Dracos, NuFact08 27 New ideas 2.5 m minimize power dissipation and radiation problems (pulser problems remain as before) protons protons 2.5 m protons same decay tunnel Ø 3 m protons to be studied in EUROn 2 options: •send at the same time 1 MW per target/horn system •send 4 MW/system every 50/4 Hz possibility to use solid target? 30 June 2008 M. Dracos, NuFact08 28 New (crazy) ideas use a cryogenic horn (toroidal coil) superconducting wire (1 mm Ø) in superfluid He, DC power supply blow gas He to avoid quenching problems •No problem with power supply (pulser no more needed) •Proton compressor no more needed 30 June 2008 M. Dracos, NuFact08 to be studied in EUROn 29 Conclusions • Proton driver characteristics and target have to be fixed before horn design. • Preliminary studies about horn focusing performance for SPL already exist. • Collector studies are necessary to increase the system lifetime. • Target/horn integration to be considered since the beginning. • Multi-physics simulations would be very useful. • New studies will start soon in the framework of EUROn FP7 project. 30 June 2008 M. Dracos, NuFact08 30 End 30 June 2008 M. Dracos, NuFact08 31