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A new method of measuring the muon g-2 Francis J.M. Farley Trinity College Dublin.

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Presentation on theme: "A new method of measuring the muon g-2 Francis J.M. Farley Trinity College Dublin."— Presentation transcript:

1 A new method of measuring the muon g-2 Francis J.M. Farley Trinity College Dublin

2 There is more than one way to kill a cat

3 Four ways to measure the muon anomalous moment = (g-2)/2 Three have been shown to work Fourth not yet tried...... might be best of all Trap muons in a magnetic field..... many turns If g = 2 the spin turns with the momentum If spin turns faster, you measure the difference g -2 Tests a fundamental prediction of the standard model µ a

4

5 Henry, Shrank & Swanson 1969 µ a Measured to 6% Below theory.... but if one applies pitch correction it is close

6 No pulse magnets.... muons make 1600 turns and emerge spontaneously at the other end Charpak et al. 1961, 1962 µ a Measured to 0.4 % agree with theory

7 Charpak, Farley, Nicolai, Sens, Zichichi, York, Garwin

8 Lederman Zichichi Charpak, Farley, Zichichi Zichichi et al started g-2 at CERN

9 Bailey et al. 1968, 1972 µ a Measured to 270 ppm primary target proton beam CERN muon storage ring 1.2 GeV 27 s τ µ

10 Bailey van der Meer Picasso Krienen Combley

11 pulsed inflector pion injection vertical focus by electric quadrupoles uniform field zero gradient "magic energy" 3.1 GeV radial electric field does not affect g-2 frequency τ = 64 sec µ g-2 frequency is same at all radii 14m diameter muon storage ring at CERN

12 CERN 1.2 GeV gradient field, weak focusing Muon storage rings τ 27 proton injection CERN 3.1 GeV uniform field, electric focusing 64 pion injection muon injection BNL 3.1 GeV uniform field, electric focusing64 Vernon Hughes started BNL experiment Sulak got BU involved Roberts Miller

13 Sulak Debevec, Farley, Hertzog, Roberts, Bunce, Krienen, Morse, Hughes, Jungmann, Semertzidis

14

15 Blind analysis... magnetic field evaluated by one group g-2 frequency evaluated by another group take ratio to calculate Overall mean = 0.001 165 920 82 ( 55) 0.47 ppm µ a G.W. Bennett et al. Phys. Rev. Lett. 92, 161802 (2004) µ a 3 separate runs & agree with each other µ- + µ

16 including KLOE Exp - th = 25.2 ± 9.2 x 10 2.7 sigma -11 from Hoecker hep-ph/0410081 v2 Comparison with theory

17 subdivide the detectors to reduce signal overlap more muons by improving pi - mu decay channel data taking in 2009 -2010 aim to halve the error using same superconducting ring magnet larger aperture inflector Plans at Brookhaven higher magnetic field B... impossible with electric focusing... breakdown To go further you need more g-2 cycles to measure The future OR say goodbye to the magic energy 3.1 GeV cannot use electric focusing go to higher energy..... increase lifetime need an AG ring

18 Increase energy to 15 GeV 5 x more g-2 cycles to measure muon lifetime –––> 320 sec µ abandon static NMR To calibrate the magnetic field use horizontally polarized protons in flight i e use proton g-2 to calibrate muon g-2 polarized proton source and polarimeter in use in RHIC a = 1.789 284 739 (30 ppb) Use AG focusing need B independent of orbit radius momentum compaction factor = dR / dp = 1 α ? increase B to 3 - 4 T ? AG muon storage ring 10 x more cycles to measure

19 Momentum compaction factor = dR / dp = 1 α h Well-known formula = 1 / 2 α Q Courant & Snyder, Annals of Physics (1958) horizontal resonance α If = 1, Q = 1 h Ring design Example: weak focusingQ = (1 - n) h √ α =1 / (1 - n) Experts say you cannot have = 1 α

20

21 Q vs open wedge angle for 4 sector ring Q v Q h

22 B = 4.5 T = 3.8 T bend radius 12 m straight sections 4.3 m momentum 15 GeV/c Q 1.025 Q 0.4 v h muon lifetime 320 s μ 3 sector concept need 10 billion recorded decay electrons say 50 billion injected muons

23 Advantages no electric quadrupoles no trolley calibration correction for diamagnetism in water paramagnetism in surrounding materials no inflector to cancel the field in the magnet at injection simple kicker using ferrite higher energy... e g 15 GeV increased accuracy longer lifetime reduces the counting rate less signal overlap less residual flash higher magnetic fields increased accuracy

24 Nuclear Instruments and Methods, A 523 (2004) 251 A new ring structure for muon g-2 measurements Francis J. M. Farley hep-ex/0307024

25 Is it worth it ?? Reduce error in a to 50 ppb........... ! ! ! µ Historically experiment has often been ahead of theory uncertainty in theory is 500 ppb theorists will want to know if they are right hadronic contribution calculated by lattice QCD when new physics is discovered it will have its effect on a µ fine structure Lamb shift Kusch & Foley Zeeman effect Stern Gerlach...... but it will improve Let's give the theorists need something to think about In fact they have something to think about already

26 HAPPY BIRTHDAY LARRY Bonne continuation

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