GDR NEUTRINO - SESSION April, LPNHE Neutrinos options at CERN R. Garoby – 27/04/2009
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/20092 OUTLINE 1.Context: plans for future LHC injectors 2.Potential neutrino options 2.1 “Conventional” beams: -CNGS -SPS with the new injectors -Low energy “Super-beam” 2.2 Neutrino Factory 2.3 Beta beams 3.Summary
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/20093 Plans for future LHC injectors
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/20094 Motivation 1. Reliability The present accelerators are getting old (PS is 48 years old !) and they operate far beyond their initial design parameters need for new accelerators designed for the needs of SLHC 2. Performance Brightness N/ * of the beam in LHC must be increased beyond the capability of the present injectors to allow for phase 2 of the LHC upgrade. [Excessive incoherent spacecharge tune spreads Q SC at injection in the PSB and PS]. need to increase the injection energy in the synchrotrons Increase injection energy in the PSB from 50 to 160 MeV kinetic Increase injection energy in the SPS from 25 to 50 GeV kinetic Design the PS successor (PS2) with an acceptable space charge effect for the maximum beam envisaged for sLHC => injection energy of 4 GeV.
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/20095 Description PSB SPS SPS+ Linac4 (LP)SPL PS LHC / SLHC DLHC Output energy 160 MeV 1.4 GeV 4 GeV 26 GeV 50 GeV 450 GeV 1 TeV 7 TeV ~ 14 TeV Linac2 50 MeV LP-SPL: Low Power - Superconducting Proton Linac (4-5 GeV) PS2: High Energy PS (~ 5 to 50 GeV – 0.3 Hz) SPS+: Superconducting SPS (50 to1000 GeV) sLHC: “Super-luminosity” LHC (up to cm -2 s -1 ) DLHC: “Double energy” LHC (1 to ~14 TeV) Proton flux / Beam power PS2
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/20096 PS2 parameters PS2 goals: to provide the beam brightness required by all sLHC options to improve SPS operation in fixed target mode
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/20097 PS2 injector Requirements of PS2 on its injector:
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/20098 Why an SPL? An H - linac combined with charge exchange injection in the following synchrotron is a proven solution for reliably reaching high beam brightness, Superconducting accelerating structures allow for reaching 4 GeV with a single accelerator (minimum beam loss/irradiation + maximum reliability), An SPL provides a large potential of extension to adapt to future needs. Among the identified possibilities: –Radioactive ion beam facility (4 MW at ~ 2.5 GeV) –Proton driver for a neutrino factory (4 MW at 5 GeV) [design available] –e+/e- acceleration to ~20 GeV (using recirculation in the =1 part of the SPL) for LHeC [preliminary study in progress] Large synergy with other projects (ESS, ADS, EURISOL, SNS…) and access to EU support for R & D.
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/20099 Implementation of the new injectors: Stage 1 (1/2) LINAC4 Ion speciesH-H- Output kinetic energy160 MeV Bunch frequency352.2 MHz Max. repetition rate1.1 (2) Hz Beam pulse duration0.4 (1.2) ms Chopping factor (beam on)62% Source current80 mA RFQ output current70 mA Linac current64 mA Average current during beam pulse40 mA Beam power5.1 kW Particles / pulse10 14 Beam characteristics H - source RFQ chopper DTL CCDTLPIMS 3 MeV 50 MeV 102 MeV MHz 160 MeV Layout
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Implementation of the new injectors: Stage 1 (2/2) Milestones End CE works: December 2010 Infrastructure: 2011 Installation: Commissioning: Modifications PSB: shut-down 2013/14 Beam from PSB: 1rst of April 2014
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Implementation of the new injectors: Stage 2 (1/4) LP-SPL + PS2 H - source RFQ chopper DTL CCDTLPIMS 3 MeV 50 MeV 102 MeV MHz β=0.65β= MeV 4 GeV MHz 160 MeV Linac4 (160 MeV)SC-linac (4 GeV) Kinetic energy (GeV)4 Beam power at 4 GeV (MW)0.12 Rep. period (s)0.6 Protons/pulse (x )1.1 Average pulse current (mA)20 Pulse duration (ms)0.9 LP-SPL beam characteristics Length: 470 m
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Implementation of the new injectors: Stage 2 (2/4) LP-SPL + PS2 Construction of LP-SPL and PS2 will not interfere with the regular operation of Linac4 + PSB for physics. Similarly, beam commissioning of LP-SPL and PS2 will take place without interference with physics. First milestones Project proposal: Project start: January 2013 Critical path: Design Study & Civil Engineering! DRAFT
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Implementation of the new injectors: Stage 2 (3/4) Site layout SPS PS2 SPL Linac4 PS ISOLDE
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Implementation of the new injectors: Stage 2 (4/4)
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Implementation of the new injectors: Stage 3 (1/2) HP-SPL H - source RFQ chopper DTL CCDTLPIMS 3 MeV 50 MeV 102 MeV MHz β=0.65β= MeV 5 GeV MHz 160 MeV Linac4 (160 MeV)SC-linac (5 GeV) Option 1Option 2 Energy (GeV)2.5 or 52.5 and 5 Beam power (MW)>2 MW (2.5 GeV) or >4 MW (5 GeV) 4 MW (2.5 GeV) and 4 MW (5 GeV) Rep. frequency (Hz)50 Protons/pulse (x )1.12 (2.5 GeV) + 1 (5 GeV) Av. Pulse current (mA)2040 Pulse duration (ms) (2.5 GeV) (5 GeV) HP-SPL beam characteristics
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Implementation of the new injectors: Stage 3 (2/2) HP-SPL The upgrade from LP-SPL to HP-SPL will depend upon the approval of major new physics programmes for Radioactive Ion beams (EURISOL-type facility) and/or for neutrinos (Neutrino factory). Staged hardware upgrade during shutdowns Earliest year of operation: >2020
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Potential neutrino options
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ CONVENTIONAL BEAMS: CNGS (1/2) CERN Gran Sasso From SPS: 400 GeV/c Cycle length: 6 s Extractions: –2 separated by 50ms Pulse length: 10.5 s Beam intensity: –2x 2.4 · ppp 0.5 mm Beam performance: –4.5· pot/year Proton beam characteristics 732 km baseline –From CERN to Gran Sasso (Italy) [Elevation of 5.9°] –Far detectors: OPERA (1.21 kt), Icarus (600 t) Commissioned 2006 Operational since 2007 from E. Gschwendtner
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ CONVENTIONAL BEAMS: CNGS (2/2) 43.4m 100m 1095m18m5m 67m 2.7m TBID Air cooled graphite target magazine –4 in situ spares –2.7 interaction lengths –Target table movable horizontally/vertically for alignment TBID multiplicity detector 2 horns (horn and reflector) –Water cooled, pulsed with 10ms half-sine wave pulse of up to 150/180kA, 0.3Hz, remote polarity change possible Decay pipe: –1000m, diameter 2.45m, 1mbar vacuum Hadron absorber: –Absorbs 100kW of protons and other hadrons 2 muon monitor stations: muon fluxes and profiles p + C (interactions) , K + (decay in flight) from E. Gschwendtner
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ CONVENTIONAL BEAMS: SPS with new injectors (1/3) from M. Meddahi
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ CONVENTIONAL BEAMS: SPS with new injectors (2/3) from M. Meddahi
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ CONVENTIONAL BEAMS: SPS with new injectors (3/3) Performance range: 2 – 4 x flux for CNGS from M. Meddahi
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ FACTORY: SPL-based proton driver (1/4) FACTORY: SPL-based proton driver (1/4) An HP-SPL based 5 GeV – 4 MW proton driver has been designed [HP-SPL + 2 fixed energy rings (accumulator & compressor)] Feasibility Study of Accumulator and Compressor for the 6- bunches SPL based Proton Driver from M. Aiba
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Compressor [120 ns bunch - V(h=3) = 4 MV] Target [2 ns bunches – 5 times] FACTORY: SPL-based proton driver (2/4) FACTORY: SPL-based proton driver (2/4) Accumulation Duration = 400 s Compression t = 0 s t = 12 s t = 24 s t = 36 s etc. until t = 84 s Accumulator [120 ns pulses - 95 ns gaps] SPL beam [42 bunches - 33 gaps]
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ FACTORY: SPL-based proton driver (3/4) FACTORY: SPL-based proton driver (3/4) from M. Aiba
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ FACTORY: SPL-based proton driver (4/4) FACTORY: SPL-based proton driver (4/4) from M. Aiba Only the accumulator would be needed for a low energy superbeam
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ =100 BEAM FACILITY: Principle Aim: production of (anti-)neutrino beams from the beta decay of radio-active ions circulating in a storage ring –Similar concept to the neutrino factory, but parent particle is a beta-active isotope instead of a muon. Beta-decay at rest – spectrum well known from electron spectrum –Reaction energy Q typically of a few MeV Accelerate parent ion to relativistic max –Boosted neutrino energy spectrum: E 2 Q –Forward focusing of neutrinos: 1/ Pure electron (anti-)neutrino beam! –Depending on + - or - - decay we get a neutrino or anti-neutrino –Two different parent ions for neutrino and anti-neutrino beams Physics applications of a beta-beam –Primarily neutrino oscillation physics and CP-violation –Cross-sections of neutrino-nucleus interaction Aim: production of (anti-) beams from the decay of radio-active ions circulating in a storage ring Similar concept to the factory, but parent particle is a -active isotope instead of a . Beta-decay at rest spectrum well known from electron spectrum Reaction energy Q typically of a few MeV Accelerate parent ion to relativistic max Boosted energy spectrum: E 2 Q Forward focusing of : 1/ Pure electron (anti-) beam! Depending on + - or - - decay we get a or anti- Two different parent ions for and anti- beams Physics applications of a beta-beam Primarily oscillation physics and CP-violation Cross-sections of -nucleus interaction from E. Wildner
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ BEAM FACILITY: EURISOL scenario Based on CERN boundaries Ion choice: 6 He and 18 Ne Based on existing technology and machines –Ion production through ISOL technique –Bunching and first acceleration: ECR, linac –Rapid cycling synchrotron –Use of existing machines: PS and SPS Relativistic gamma=100 for both ions –SPS allows maximum of 150 ( 6 He) or 250 ( 18 Ne) –Gamma choice optimized for physics reach Opportunity to share a Mton Water Cherenkov detector with a CERN super-beam, proton decay studies and a neutrino observatory Achieve an annual neutrino rate of –2.9*10 18 anti-neutrinos from 6 He – neutrinos from 18 Ne The EURISOL scenario will serve as reference for further studies and developments: Within Euro we will study 8 Li and 8 B top-down approach from E. Wildner
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ BEAM FACILITY: Ions production schemes (1/2) ISOL method at 1-2 GeV (200 kW) > He per second < Ne per second Studied within EURISOL Direct production > (?) 6 He per second Ne per second Studied at LLN, Soreq, WI and GANIL Production ring (?) 8 Li > (?) 8 B Will be studied within EURO- Courtesy M. Lindroos Aim: He ( /s) Ne ( /s) from E. Wildner
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ BEAM FACILITY: Ions production schemes (2/2) Courtesy M. Lindroos from E. Wildner
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Summary
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ (1/2) There has been significant progress during the past years in the definition of CERN future proton accelerators for the needs of LHC The possibility to upgrade to high beam power has been studied and kept compatible with the proposals HOWEVER Schedule is continuously shifting (level of resources + better understanding of Civil Engineering needs…) Numerous issues deserve special investigation to prepare for multi-MW proton drivers (Beam dynamics and hardware design for the accelerators, Design of target and target area…) The possibility to upgrade to high beam power will have a cost: approval by the CERN Council cannot be taken as granted.
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ (2/2) MILESTONES 2009: “Definition of the CERN scientific strategy” May 2009: workshop on New Opportunities in the Physics Landscape at CERNNew Opportunities in the Physics Landscape at CERN September 2009: workshop on neutrino physics (organized by a working group of the CERN SPC) 2012: “Authorization of the new projects” June 2012: Council decision (the whole planning is locked on the starting date) If the case for a high power SPL is strong, it would be ideal to immediately implement it. If the high power option is considered of too low interest, the investment required to implement it later can be rejected. End of 2010’s: “Start of commissioning of sLHC”
GDR NEUTRINO - SESSION April, LPNHE
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ SPARE SLIDES
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ PIMS A 70 m long transfer line connects to the existing line Linac2 - PS Booster Linac4 accelerating structures Linac4 accelerates H- ions up to 160 MeV energy: in about 80 m length using 4 different accelerating structures, all at 352 MHz the Radio-Frequency power is produced by 19 klystrons focusing of the beam is provided by 111 Permanent Magnet Quadrupoles and 33 Electromagnetic Quadrupoles
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Linac4 civil engineering Linac4 tunnel Linac4-Linac2 transfer line Equipment building Access building Low-energy injector ground level
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Equipment Hall (Bld. 400)
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Linac4 tunnel cross-section Final position of cable trays:
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ REFERENCES - SPL -
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ MHz1408 MHz 352 MHz (spoke) MHz length 439 m+14%+10% N cavities %+12% N β-families tr. beam loss --- jitter medium ε-growth (x/y/z) 5.6/8.2/6.86.3/7.8/ /5.3/2.5 trans. beam loading --- BBU (HOM) I BBU,704 1/(8..128)higher/lower trapped modes normal risk2..4 higher risk?/higher SC gradients --- field control more complex Comparison of frequencies (1/2)
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ MHz1408 MHz 352 MHz (spoke) MHz cryo-modules ~ ILC 2 different types cooling K 15.3 kW15.5 kW? klystrons comfortable: MBKdifficultexisting/difficult RF power coupler feasible RF power density limit (distribution) okproblematicbulky/problematic overall power consumption (RF+cryo, nom. SPL) 28 MW-30%? power converter more bulkysaves tunnel space- synergy with ESS yesno Comparison of frequencies (2/2)
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Conclusions of the assessment
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ SPL cryomodules
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ REFERENCES - Site Layouts (Stage 3) -
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Plan for a Radioactive Ion Beam Facility (Stage 3) HP-SPL TARGETS RADIOACTIVE IONS LINAC EURISOL EXPERIMENTAL HALLS ISOLDE OR EURISOL HIGH ENERGY EXPERIMENTAL HALL TRANSFER LINES SPL to EURISOL TRANSFER LINE SPL to ISOLDE
GDR NEUTRINO - SESSION April, LPNHE R.G. 27/04/ Plan for a Neutrino Factory (Stage 3) MUON PRODUCTION TARGET MUON ACCELERATORS MUON STORAGE RING SPL ACCUMULATOR & COMPRESSOR