Cool Muon Colliders

Cool Muon Colliders Studies at Columbia University & Nevis Labs Raphael Galea Allen Caldwell Stefan Schlenstedt (DESY/Zeuten) Halina Abramowitz(Tel Aviv University) Summer Students: Christos Georgiou Daniel Greenwald Yujin Ning Inna Shpiro Will Serber

Cool Muon Colliders: Caltech October 9, 2001 Outline • Muon Colliders Motivation • History • Physics • Higgs, neutrino physics, new & old physics • Cooling obstacle • Ionization cooling • Frictional cooling

Cool Muon Colliders: Caltech October 9, 2001 History • Concept first proposed to Budker & Skrinsky in 60’s and early 70’s • Ionization cooling developed by Skrinsky & Parkhomchuk in 1981 • Furthered by Neuffer & Palmer resulting in formation of Muon Collider collaboration in 1995

Cool Muon Colliders: Caltech October 9, 2001 The Future • Lepton Collider clean but limited in energy by synchrotron radiationa 1/m^4 • Hardron Collider higher energy Mp~2000xMe • 1/3-1/10 energy taking part in collision • Difficult to separate the underlying event • Muon Collider • Not limited by synchrotron radiation Mm~200xMe • Easily scaleable • Compact machines

Cool Muon Colliders: Caltech October 9, 2001

Cool Muon Colliders: Caltech October 9, 2001 Livingston Curve

Cool Muon Colliders: Caltech October 9, 2001 Muon Collider in Perspective

Cool Muon Colliders: Caltech October 9, 2001 Physics Motivation • m+m- couple directly to Higgs • S channel • Muons can be polarized (20% polarization will be achievable) • High beam resolution • If proven technology machine scalable • High mass resonances,technicolour, SUSY… • Cool muons can be used as a source of n’s HIGGS FACTORY

Cool Muon Colliders: Caltech October 9, 2001 Higgs Factory

Cool Muon Colliders: Caltech October 9, 2001 Higgs Properties • Scan 0.0015fb-1/point • 1 year of running at L=1.5x1031cm-2 s-1 • (0.15fb-1)/year to measure Higgs mass to 1-2 MeV

Cool Muon Colliders: Caltech October 9, 2001 Light Higgs • Gh=2-3 MeV • Gh=2-3 MeV for tanb<2 • Gh=2-500 MeV for tanb~50

Cool Muon Colliders: Caltech October 9, 2001 Resolving Mass Degeneracies

Cool Muon Colliders: Caltech October 9, 2001 No Higgs @ LHC?? With 10fb-1 of lumi devoted to threshold scan: m+m- W+W- Dm(W)=20MeV m+m- t+t- Dm(t)=200MeV m+m- Zh Dm(h)=140MeV

Cool Muon Colliders: Caltech October 9, 2001 Supersymmetry • 50fb-1 can lead to DM(c+)=35,45MeV for • M(c+)=100 MeV & M(v)=500,300 GeV • Heavy SUSY scalar pair production is p-wave suppresseM=1TeV requires collider of 3-4TeV CMS

Cool Muon Colliders: Caltech October 9, 2001 Cooling Motivation • p produced by intense p beam on target • p captured by strong focusing field • p to m • Resulting muons occupy large & diffuse phase space

Cool Muon Colliders: Caltech October 9, 2001 Ionization Cooling • Transverse Cooling • Muons lose energy by dE/dx & replaced longitudinally by RF • High field solenoids • low Z absorbers

Cool Muon Colliders: Caltech October 9, 2001 Longitudinal Cooling • Ionization cooling using a wedge absorber + dispersion • Exchange emittance between transverse & longitudinal direction

Cool Muon Colliders: Caltech October 9, 2001 Frictional Cooling • Bring muons to a kinetic energy (T) range where dE/dx increases with T • Constant E-field applied to muons resulting in equilibrium energy

Cool Muon Colliders: Caltech October 9, 2001 Problems/Comments: • large dE/dx @ low kinetic energy • low average density • Apply to get below the dE/dx peak • m+has the problem of Muonium formation • s(Mm) dominates over e-stripping s in all gases except He • m-has the problem of Atomic capture • s calculated up to 80 eV not measured below ~1KeV • Cool m’s extracted from gas cell T=1ms so a scheme for reacceleration must be developed

Cool Muon Colliders: Caltech October 9, 2001 Basic Design

Cool Muon Colliders: Caltech October 9, 2001 Muon Motion in Cooling Cell

Cool Muon Colliders: Caltech October 9, 2001 Target Optimization • Want low energy muons hence need to optimize pion production accordingly for: • Proton Driver Energy • Target Material • Target Dimensions • Target Orientation Peripheral Central

Cool Muon Colliders: Caltech October 9, 2001 Magnet Capture Peripheral Central p p+,m+ p+ p- m+ m- p p-,m- • +ve & -ve in same channel • Separate charges at source

Cool Muon Colliders: Caltech October 9, 2001 Phase Rotation • Apply simple E-field form : • Optimize muon yield as a function of t1,t2 & Length of the phase rotation region Emax t1 t2

Cool Muon Colliders: Caltech October 9, 2001 Multiple Scattering • To date simulations only considered continuous dE/dx • May turn out that component of E-fieldparallel to B-field needed • Technically difficult because of large angle scatters at low energies

Cool Muon Colliders: Caltech October 9, 2001 PSI Experiment • Experiment study Lamb Shift in Muonic Atoms • Muon Spectrum 10-40KeV • 5T Magnet with D=20cm bore

Cool Muon Colliders: Caltech October 9, 2001 Nevis Setup

Vary E-field, density & length of gas cell Simulation with no Multiple Scattering E-field parallel to B-field so muons do not stop Cool Muon Colliders: Caltech October 9, 2001 Simulation @ Nevis

Cool Muon Colliders: Caltech October 9, 2001 Goals of Experiment • Measure X-ray released from capture in Gas Atom • Check understanding of energy loss, multiple scattering • Measure m- capture cross section at low energies in He & H2

Cool Muon Colliders: Caltech October 9, 2001 Nevis lab: • Multipurpose Vacuum Chamber • Fast Logic Readout • MCP Detector • X-ray MWPC development underway

Cool Muon Colliders: Caltech October 9, 2001 MWPC X-ray Detector • 4 channel prototype • Possible extension to tracker – track decay e- from captured m-

Cool Muon Colliders: Caltech October 9, 2001 Summary • Muon Colliders promise a bright future for HEP • Physics Factory, Higgs, n’s, s-channel resonances • Major hurdle is cooling but efforts are going forward with a plan to demonstrate emittance exchange • Exciting alternative concept for muon cooling • Frictional Cooling • Possibility to cool both signs at once • Experiment to measure m- capture cross section planned…..STAY TUNED

Cool Muon Colliders