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Stephen Brooks / RAL / April 2004 Muon Front Ends Providing High-Intensity, Low-Emittance Muon Beams for the Neutrino Factory and Muon Collider
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Stephen Brooks / RAL / April 2004 Contents Future Accelerator Projects Requiring Muon Front Ends –Neutrino Factory –Muon Collider Choice of Particle – why Muons? Design Components and Options Research Currently Underway –By both Grahame Rees and myself
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Stephen Brooks / RAL / April 2004 The Neutrino Factory Goal: To fire a focussed beam of neutrinos through the interior of the Earth –What’s the point? Constrains post-Standard Model physics –But why does this involve muons? Neutrinos appear only as decay products Decaying an intense, high-speed beam of muons produces collimated neutrinos
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Stephen Brooks / RAL / April 2004 The Neutrino Factory p + + + e + e Uses 4-5MW proton driver –Could be based on ISIS
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Stephen Brooks / RAL / April 2004 The Muon Collider Goal: to push the energy frontier in the lepton sector after the linear collider p + +, − +, − +-+- 3+3TeV Muon Collider Ring
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Stephen Brooks / RAL / April 2004 Why Collide Muons? ParticleProtonElectronMuon Mass938 MeV511 keV106 MeV Synchrotron radiation limit (LEP-II RF) 28.5 TeV102 GeV5.55 TeV Same length of 100MV/m L.C. 1.33 TeV Bending field limit (LHC) 7 TeV Problems Messy collisions None Half-life of 2.2 s
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Stephen Brooks / RAL / April 2004 Design Challenges Must accelerate muons quickly, before they decay –Synchrotron acceleration is too slow –But once is high, you have more time High emittance of pions from the target –Use an accelerator with a really big aperture? –Or try beam cooling (emittance reduction) –In reality, do some of both
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Stephen Brooks / RAL / April 2004 Muon Front End Components Targetry, produces pions ( ± ) Pion to muon decay channel –Uses a series of wide-bore solenoids “Phase rotation” systems –Aim for either low E or short bunch length Muon ionisation cooling (as in “MICE”) –Expensive components, re-use in cooling ring Muon acceleration (RLAs vs. FFAGs)
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Stephen Brooks / RAL / April 2004 The Decay Channel Has to deal with the “beam” coming from the pion sourcepion source Pion half-life is 18ns or 12m at 200MeV –So make the decay channel about 30m long Grahame designed an initial version –Used S/C solenoids to get a large aperture and high field (3T mostly, 20T around target) Needed a better tracking code…
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Stephen Brooks / RAL / April 2004 The Decay Channel (ctd.) Developed a more accurate code Used it to validate Grahame’s design… –3.1% of the pions/muons were captured …and parameter search for the optimum –Within constraints: 0.5m drifts, etc. –Increased transmission to 9.6% Increased in the older code (PARMILA) too –Fixed a problem in the original design!
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Stephen Brooks / RAL / April 2004 Two Phase Rotation Options Chicane (2001) –FFAG-style magnets –Shortens the bunch –Have optimised matching 2.4% net transmission –No cooling? 31.4MHz RF (2003) –Reduces the energy spread 180±75MeV to ±23MeV –Feeds into cooling ring
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Stephen Brooks / RAL / April 2004 RAL Design for Cooling Ring 10-20 turns Uses H 2 (l) or graphite absorbers Cooling in all 3 planes 16% emittance loss per turn (probably) Tracking and optimisation later this year…
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Stephen Brooks / RAL / April 2004 BACKUP! In case the time is longer than my slides. Web report
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Stephen Brooks / RAL / April 2004 Muon Acceleration Options Accelerators must have a large aperture Few turns (or linear) in low energy part, so muons don’t decay Recirculating Linacs (RLAs, studied first) FFAGs (cyclotron-like devices) –Grahame is playing with isochronous ones
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Stephen Brooks / RAL / April 2004 NuFact Intensity Goals “Success” is 10 21 /yr in the storage ring Proton Energy/GeVIntensity/MWTarget eff (pi/p)MuEnd eff (mu/pi)Operationalmu/year in storage ringCurrent/uA 8420%1.0%30% 5.90497E+19500 "Not great" scenario 8160%2.0%35% 1.03337E+20125 ISIS MW only to reach 10^20 8560%3.5%40% 1.03337E+21625 "Quite good" 5MW scenario (gets 10^21) 851.758.5%55% 1.00646E+22625 Required to reach 10^22 1.75 = PtO2 target inclined at 200mrad, see Mokhov FNAL PiTargets paper20% = 2.2GeV dataset from Paul Drumm
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Stephen Brooks / RAL / April 2004 Tracking & Optimisation System Distributed Computing –~450GHz of processing power –Can test millions of designs Genetic Algorithms –Optimisation good up to 137 parameters… Accelerator design-range specification language –Includes “C” interpreter
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Stephen Brooks / RAL / April 2004 The Decay Channel Has to deal with the “beam” coming from the pion source Evolution of pions from 2.2GeV proton beam on tantalum rod target
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Stephen Brooks / RAL / April 2004 Decay Channel Lattice Drifts Length (m) D10.5718 [0.5,1] D2+0.5 [0.5,1] Solenoids Field (T)Radius (m)Length (m) S1 20 [0,20] 0.1 [fixed] 0.4066 [0.2,0.45] S2-4 −3.3, 4, −3.3 [-5,5] 0.3 [0.1,0.4] 0.4 [0.2,0.6] S5-S24 ±3.3 (alternating) [-4,4] S25+ 0.15 [0.1,0.4] Final (S34)0.15 [fixed] 12 parameters –Solenoids alternated in field strength and narrowed according to a pattern 137 parameters –Varied everything individually Tantalum Rod Length (m)0.2 [fixed] Radius (m)0.01 [fixed] Angle (radians)0.1 [0,0.5] Z displacement (m) from S1 start 0.2033 (S1 centred) [0,0.45] Original parameters / Optimisation ranges
![ Stephen Brooks / RAL / April 2004 Decay Channel Lattice Drifts Length (m) D [0.5,1] D2+0.5 [0.5,1] Solenoids Field (T)Radius (m)Length (m) S1 20 [0,20] 0.1 [fixed] [0.2,0.45] S2-4 −3.3, 4, −3.3 [-5,5] 0.3 [0.1,0.4] 0.4 [0.2,0.6] S5-S24 ±3.3 (alternating) [-4,4] S [0.1,0.4] Final (S34)0.15 [fixed] 12 parameters –Solenoids alternated in field strength and narrowed according to a pattern 137 parameters –Varied everything individually Tantalum Rod Length (m)0.2 [fixed] Radius (m)0.01 [fixed] Angle (radians)0.1 [0,0.5] Z displacement (m) from S1 start (S1 centred) [0,0.45] Original parameters / Optimisation ranges](http://images.slideplayer.com/27/8960103/slides/slide_18.jpg " Stephen Brooks / RAL / April 2004 Decay Channel Lattice Drifts Length (m) D [0.5,1] D2+0.5 [0.5,1] Solenoids Field (T)Radius (m)Length (m) S1 20 [0,20] 0.1 [fixed] [0.2,0.45] S2-4 −3.3, 4, −3.3 [-5,5] 0.3 [0.1,0.4] 0.4 [0.2,0.6] S5-S24 ±3.3 (alternating) [-4,4] S [0.1,0.4] Final (S34)0.15 [fixed] 12 parameters –Solenoids alternated in field strength and narrowed according to a pattern 137 parameters –Varied everything individually Tantalum Rod Length (m)0.2 [fixed] Radius (m)0.01 [fixed] Angle (radians)0.1 [0,0.5] Z displacement (m) from S1 start (S1 centred) [0,0.45] Original parameters / Optimisation ranges")
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Stephen Brooks / RAL / April 2004 Improved Transmission Decay channel: –Original design: 3.1% + out per + from rod –12-parameter optimisation 6.5% + / + 1.88% through chicane –137 parameters 9.6% + / + 2.24% through chicane Re-optimised for chicane transmission: –Original design got 1.13% –12 parameters 1.93% –137 parameters 2.41% 3`700`000 runs so far 1`900`000 runs 330`000 runs
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Stephen Brooks / RAL / April 2004 Optimised Design for the Decay Channel (137 parameters) Maximum Length Minimum Drift Maximum Aperture Maximum Field (not before S6) (mostly) (except near ends) (except S4, S6)
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Stephen Brooks / RAL / April 2004 Why did it make all the solenoid fields have the same sign? Original design had alternating (FODO) solenoids Optimiser independently chose a FOFO lattice Has to do with the stability of off-energy particles FODO lattice FOFO lattice
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Stephen Brooks / RAL / April 2004 Design Optimised for Transmission Through Chicane Nontrivial optimum found Preferred length? Narrowing can only be due to nonlinear end-fields
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