Post on 26-Jul-2020
1
Muon Cooling and the Muon ColliderA. Caldwell
MPI f. Physik
• Motivation• Difficulties• Focus on Cooling (frictional cooling)
2
Why a Muon Collider ?
No synchrotron radiation problem (cf electron)
P α (E/m)4
Can build a high energy circular accelerator.
PCollide point particles rather than complex objects
P
3
Some Difficulties
• Muons decay, so are not readily available – need multi MW source. Large starting cost.• Muons decay, so time available for cooling, bunching, acceleration is very limited. Need to develop new techniques, technologies.• Large experimental backgrounds from muon decays (for a collider). Not the usual clean electron collider environment.• High energy colliders with high muon flux will face critical limitation from neutrino induced radiation.
4
Dimensions of Some Colliders discussed
5
Physics at a Muon Collider
• Stopped µ physics• ν physics• Higgs Factory• Higher Energy Frontier
Muon Collider Complex:• Proton Driver 2-16GeV; 1-4MW leading to 1022p /year• π production target & Strong Field Capture• COOLING resultant µ beam• µ acceleration•Storage & collisions
σµµ→Η= 40000 σee→Η
From target, stored µ
6
HIGH ENERGY MUON COLLIDER PARAMETERS
Baseline parameters for high energy muon colliders. From “Status of Muon ColliderResearch and Development and Future Plans,” Muon Collider Collaboration, C. M.Ankenbrandt et al., Phys. Rev. ST Accel. Beams 2, 081001 (1999).
COM energy (TeV) 0.4 3.0p energy (GeV) 16 16p’s/bunch 2.5 × 1013 2.5 × 1013
Bunches/fill 4 4Rep. rate (Hz) 15 15p power (MW) 4 4µ/ bunch 2 × 1012 2 × 1012
µ power (MW) 4 28Wall power (MW) 120 204Collider circum. (m) 1000 6000Ave bending field (T) 4.7 5.2rms δp/p (%) 0.14 0.166D ε6,Ν (πm)3 1.7 × 10−10 1.7 × 10−10
rms εn (π mm mrad) 50 50β* (cm) 2.6 0.3σz (cm) 2.6 0.3σr spot (µm) 2.6 3.2σθ IP (mrad) 1.0 1.1Tune shift 0.044 0.044nturns (effective) 700 785Luminosity (cm−2 s−1) 1033 7 × 1034
7
π’s in redµ’s in green
Solenoidal Magnets: few T … 20 T
Drift region for π decay ≈ 30 m
P beam (few MW)
Target
Simplified emittance estimate:At end of drift, rms x,y,z approx 0.05,0.05,10 m
Px,Py,Pz approx 50,50,100 MeV/c
Normalized 6D emittance is product divided by (mµc)3
εdrift6D,N ≈1.7 10-4 (πm)3
Emittance needed for Muon Collider εcollider
6D,N ≈ 1.7 10-10(πm)3
This reduction of 6 orders of magnitude must be done with reasonable efficiency !
8
Muon Cooling
Muon Cooling is the signature challenge of a Muon Collider
Cooler beams would allow fewer muons for a given luminosity, thereby• Reducing the experimental background• Reducing the radiation from muon decays• Reducing the radiation from neutrino interactions• Allowing for smaller apertures in machine elements, and so driving the cost down
9
Cooling Ideas
Ionization cooling (Skrinsky, Neuffer, Palmer, …): muons are maintained at ca. 200 MeV. Transverse cooling of order x20 seems feasible (see ν-factory feasibility studies 1-2). Longitudinal cooling not solved.
Gas cell
RF
B B
µ beam
10
Longitudinal Cooling via Emittance Exchange
Transform longitudinal phase space into transverse (know how to cool transverse)
Wedge shaped absorber
Bent solenoid produces dispersion
11
‘Balbekov Ring’
There are significant developments in achieving 6D phase space via ionization cooling (R. Palmer, MUTAC03), but still far from 106 cooling factor.
12
13
KEK – focus on FFAG acceleration
Frictional CoolingFrictional Cooling
Studies at Columbia University/MPIStudies at Columbia University/MPIAllen Caldwell, Raphael Allen Caldwell, Raphael GaleaGalea
++Stefan Stefan Schlenstedt Schlenstedt (DESY/(DESY/ZeuthenZeuthen))
Halina AbramowiczHalina Abramowicz (Tel Aviv University)(Tel Aviv University)
Summer Students: Summer Students: Emily AldenEmily AldenChristos Georgiou Christos Georgiou Daniel GreenwaldDaniel GreenwaldLaura NewburghLaura NewburghYujin NingYujin NingInna Inna ShpiroShpiroWill Will SerberSerber
15
Frictional CoolingFrictional Cooling
• Bring muons to a kinetic energy (T) where dE/dxincreases with T
• Constant E-field applied to muons resulting in equilibrium energy
• Big issue – how to maintain efficiency
• Similar idea first studied by Kottmann et al., PSI
Helium
1
10
10 2
10 3
10-4
10-3
10-2
10-1
1 10 102
103
1/β2 from ionization
Ionization stops, muon too slow
Nuclear scattering, excitation, charge exchange, ionization
16
Problems/comments:Problems/comments:• large dE/dx @ low kinetic energy
⇒ low average density (gas)• Apply E ⊥ B to get below the dE/dx
peakF = q(E + vxB) – dT/dx
• µ− has the problem of Atomic captureσ small above electron binding energy,
but not known. Keep T as high as possible
• Slow muons don’t go far before decaying
d = 10 cm sqrt(T ) T in eV so extract sideways (E ⊥ B )
µ+ has the problem of Muoniumformation
σ(Μµ) dominates over e-stripping in all gases except He
Helium
1
10
10 2
10 3
10-4
10-3
10-2
10-1
1 10 102
103
17
Neutralization Stripping
For µ, energy lower by Mµ/MP
From Y. Nakai, T. Shirai, T. Tabata and R. Ito, At. Data Nucl. Data Tables 37, 69 (1987)
18
Frictional Cooling: particle trajectory
B=5 T, E=5 MV/m, ρHe=1 10-4 g/cm3
-0.06
-0.04
-0.02
0
0.02
0.04
0.06
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
B=5 T, E=5 MV/m, ρHe=1 10-4 g/cm3
-0.06
-0.04
-0.02
0
0.02
0.04
0.06
-0.06 -0.04 -0.02 0 0.02 0.04 0.06
** Using continuous energy loss
19
Frictional Cooling: stop the µPlots for1. 10-4 g/cm3 He
• High energy µ’s travel a long distance to stop• High energy µ’s take a long time to stop
10-2
10-1
1
10
10 2
10 102 10
-9
10-8
10-7
10-6
10-5
10 102
Optimize for low initial muon momentum, + phase rotation
20
Cooling cells
Phase rotation sections
Not to scale !!
Schematic Layout for µ Collider Scheme Studied
21
Detailed Simulation
Full MARS target simulation, optimized for low energy muon yield: 2 GeV protons on Cu with proton beam transverse to solenoids (capture low energy pion cloud).
22GeV
Target System
beam
π
π
Transverse(symme−tric)scheme
_
+
• cool µ+ & µ- at the same time• calculated new symmetric magnet with gap for target
23
Target & Drift Optimize yield
• Optimize drift length for µ yield• Some π’s lost in Magnet aperture
24
28m
0.4m
beam
π
π
Transverse(symme−tric)scheme
_
+
π’s in redµ’s in green
View into beamGEANT simulation
25
Phase RotationPhase Rotation
0
500
1000
1500
2000
2500
3000
3500
4000
0 200 400 600 800 1000
Pz(MeV/c)
µs
cool µs
µ After Drift
0
500
1000
1500
2000
2500
3000
0 50 100 150 200 250 300
• First attempt simple form• Vary t1,t2 & Emax for maximum low energy yield
26
Cooling cell simulationHe gas is used for µ+, H2 for µ-.
• Individual nuclear scatters are simulated – crucial in determining final phase space, survival probability.•Incorporate scattering cross sections into the cooling program•Include µ- capture cross section using calculations of Cohen (Phys. Rev. A. Vol 62 022512-1)
• Electronic energy loss treated as continuous
Cross Section Comparisons
10-18
10-17
10-16
10-15
1 10 102
27
Scattering Cross Sections
•Scan impact parameter and calculate θ(b), dσ/dθfrom which one can get λmean free path•Use screened Coulomb Potential (Everhart et. al. Phys. Rev. 99 (1955) 1287)
•Simulate all scatters θ>0.05 rad•Simulation accurately reproduces ICRU tables
28
Barkas Effect
1
10
10 2
10 3
10-3
10-2
10-1
1 10 102
103
104
•Difference in µ+ & µ-
energy loss rates at dE/dx peak•Due to charge exchange for µ+
•parameterized data from Agnello et. al. (Phys. Rev. Lett. 74 (1995) 371)
•Only used for the electronic part of dE/dx
29
Trajectories in detailed simulation
Transverse motion Longitudinal motion
Motion controlled by B field
Lorentz angle drift, with nuclear scattering
Final stages of muon trajectory in gas cell
30
Helium
1
10
10 2
10 3
10-4
10-3
10-2
10-1
1 10 102
103
Oscillations about equilibrium define emittance.
Dangerous because of µ-
capture possibility
vxB dominates
E dominates
F = q(E+v×B)-dT/dx
31
E
Initial reacceleration region
σT = 4 ns at Z=444mP = 200 MeV/cEff = 40%gas Reacc section
After gas cell, E(z,t)
32
Yields & Emittance
Look at muons coming out of 11m cooling cell region after initial reacceleration.
Yield: approx 0.002 µ per 2GeV proton after cooling cell.Need to improve yield by factor 3 or more.
Emittance: rms x = 0.015 my = 0.036 mz = 30 m ( actually βct)Px = 0.18 MeVPy = 0.18 MeVPz = 4.0 MeV
ε6D,N = 5.7 10-11 (πm)3
33
Problems/Things to investigate…
• Extraction of µs through window in gas cell •Must be very thin to pass low energy µs•Must be reasonably gas tight
• Can we apply high electric fields in gas cell without breakdown (large number of free electrons, ions) ? Plasma generation → screening of field. • Reacceleration & bunch compression for injection into storage ring• The µ− capture cross section depends very sensitively on kinetic energy & falls off sharply for kinetic energies greater than e- binding energy. NO DATA – simulations use theoretical calculation• +…
34
First try to demonstrate frictional cooling with protons.
RARAF Facility – Nevis Lab/Columbia University
≤ 4 MeV p
VandeGraafaccelerator for biomedical research
beamH2
+
36
Contains 20nm window
Proton beam
Gas cell
Accelerating grid
Vacuum chamber
To MCP
Si detector
37
38
39
The proton energy spectrum from the Si calculated using SRIM (J. F.
Ziegler, J. P. Biersack and U. Littmark, Pergamon Press, 1985). The transport through the gas performed with our detailed simulation. Need first to fix the window thickness and gas pressure.
Min Kin Energy fixed by reacc potential
40
Calibration Data:3 distances, no cell, no grid
Time resolution of system=17ns
Protons have 100-200 KeV after Si window. Good agreement with SRIM.
41
Add gas, still no field. Gas pressure extracted from comparison with simulation. Compatible with expectations.
Add cell, no gas, no E field. Extract effective window thickness by comparison with simulation. Much thicker than expected !
42
Summary of calibration using the time spectrum
43
After background subtraction, see no hint of cooled protons. Also predicted by simulation. Problem – windows too thick, acceptance, particularly for slow protons, too small. Need to repeat the experiment with solenoid, no windows.
44
Future Plans
• Frictional cooling tests at MPI with 5T Solenoid, alpha source• Study gas breakdown in high E,B fields• R&D on thin windows• Beam tests with muons to measure µ capture cross section
µ-+He → Heµ+ e+γ’s
muon initially captured in large n orbit, then cascades down to n=1. Transition n=2→n=1 releases few KeV x-ray.
Si drift detectorDeveloped my MPIHLL
45
Lab situated at MPI-WHI inMunich
46
Conclusions
• Muon Collider complex would be a boon for physics
• We need to solve the muon cooling problem
• Different schemes should be investigated• We are doing some simulation and
experimental studies of frictional cooling. So far, so good, but a long way to go !