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1) Status of the Muon g-2 Experiment 2) EDM Searches in Storage Rings Yannis K. Semertzidis Brookhaven National Lab Muon g-2 Collaboration and EDM Collaboration.

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Presentation on theme: "1) Status of the Muon g-2 Experiment 2) EDM Searches in Storage Rings Yannis K. Semertzidis Brookhaven National Lab Muon g-2 Collaboration and EDM Collaboration."— Presentation transcript:

1 1) Status of the Muon g-2 Experiment 2) EDM Searches in Storage Rings Yannis K. Semertzidis Brookhaven National Lab Muon g-2 Collaboration and EDM Collaboration HEP03 Athens, 17-20 April 2003

2 † † ‡ # Muon g-2 Collaboration †Spokesperson ‡Project Manager # Resident Spokesperson

3 Prof. Vernon W. Hughes (1921  2003)

4 g-factors: 1.Proton (g p =+5.586) and the neutron (g n =-3.826) are composite particles. 2.The ratio g p /g n =-1.46 close to the predicted -3/2 was the first success of the constituent quark model. 3.The g-2 value of the electrons is non-zero due to quantum field fluctuations involving QED. 4.g µ - 2 is more sensitive than the electron by (m µ /m e ) 2 ≈40,000.

5 g - 2 for the muon Largest contribution : Other standard model contributions : QED hadronic weak

6 Theory of a µ a µ (theo) = a µ (QED)+a µ (had)+a µ (weak) + a µ (new physics) a µ (QED) = 11 658 470.57(0.29)×10 -10 a µ (had) = 683.3 (7.7) ×10 -10 (based on e + e - ) a µ (weak) = 15.1 (0.4) ×10 -10 a µ (SM) = 11 659 169(7.7)×10 -10

7 Theory of a µ a µ (theo) = a µ (QED)+a µ (had)+a µ (weak) + a µ (new physics) a µ (QED) = 11 658 470.57(0.29)×10 -10 a µ (had) = 683.3 (7.7) ×10 -10 (based on e + e - ) a µ (weak) = 15.1 (0.4) ×10 -10 a µ (SM) = 11 659 169(7.7)×10 -10

8 Spin Precession in g-2 Ring (Top View)  Momentum vector Spin vector

9 Spin Precession in g-2 Ring (Top View)  Momentum vector Spin vector

10 The Muon Storage Ring: B ≈ 1.45T, P μ ≈3.09 GeV/c Inner Ring of Detectors High Proton Intensity from AGS Muon Injection

11 n=0.148 n=0.126 Field Focusing Index: n=0.137 Weak Focusing Ring. Tune Plane:

12 4 Billion e + with E>2GeV

13 5-parameter Function Not Quite Adequate. Fourier Spectrum of the Residuals: f g-2 ≈229 KHz f cbo ≈466 KHz

14 Modulation of N 0, A, with f cbo :

15

16 Amplitudes of A N, A A, A, Consistent with Values from MC Simulations (10 -2, 10 -3, 10 -3 respectively) Modulation of N 0, A, with f cbo :

17 Fit dN/dt of each Detector Separately with the 5-parameter (ideal) Function. Then Fit ω a versus Detector: Straight line fit: χ 2 /dof=59/21, ω a /2π=229070.60±0.14 Hz

18 Fit dN/dt of each Detector Separately with the 5-parameter (ideal) Function. Then Fit ω a versus Detector: Straight line fit: χ 2 /dof=59/21, ω a /2π=229070.60±0.14 Hz Sine wave fit: χ 2 /dof=24/19, ω a /2π=229070.64±0.14 Hz

19 Fit dN/dt with the 5-parameter Function including the Modulation of N 0, A, with f cbo. Fit ω a versus Detector: Straight line fit: χ 2 /dof=24/21, ω a /2π=229070.54±0.16 Hz

20 Function Modulating N 0, A, with f cbo. Four Independent Analyses of ω a Using Various Studies:

21 Function Modulating N 0, A, with f cbo. Function Modulating N 0, A with f cbo. Four Independent Analyses of ω a Using Various Studies:

22 Function Modulating N 0, A, with f cbo. Function Modulating N 0, A with f cbo. Strobing the data at f cbo ; ω a Becomes Independent of f cbo. Four Independent Analyses of ω a Using Various Studies:

23 Function Modulating N 0, A, with f cbo. Function Modulating N 0, A with f cbo. Strobing the data at f cbo ; ω a Becomes Independent of f cbo. Ratio Method; ω a Becomes Independent of Slow Effects, e.g. Muon Losses. Four Independent Analyses of ω a Using Various Studies:

24 Function Modulating N 0, A, with f cbo. Function Modulating N 0, A with f cbo. Strobing the data at f cbo ; ω a Becomes Independent of f cbo. Ratio Method; ω a Becomes Independent of Slow Effects, e.g. Muon Losses. Four Independent Analyses of ω a Using Various Studies: Systematic Uncertainties for the ω a Analysis. Source of Errors Size [ppm] Coherent Betatron Oscillations (CBO) Pileup Gain Changes Lost Muons Binning & Fitting Procedure Others Total 0.21 0.13 0.10 0.06 0.31

25 Magnetic Field measurement The B field azimuthal variation at the center of the storage region.  1.45 T The B field averaged over azimuth.

26 Magnetic Field Measurement Systematic Uncertainties for the ω p Analysis. Source of Errors Size [ppm] Absolute Calibration of Standard Probe Calibration of Trolley Probe Trolley Measurements of B-field Interpolation with Fixed Probes Uncertainty from Muon Distribution Others Total 0.05 0.15 0.10 0.03 0.10 0.24

27 Computation of a μ : Analyses of ω a and ω p are Separate and Independent (“Blind Analysis”). When Ready, only then, Offsets are Removed and a μ is Computed.

28 Computation of a μ : Data of 2000: a μ (exp)=11 659 204(7)(5)×10 -10 (0.7 ppm) Exp. World Average: a μ (exp)=11 659 203(8)×10 -10 (0.7 ppm) a μ (exp)- a μ (SM)=33.7(11)×10 -10, 3σ effect!

29 Cannot be calculated from pQCD alone because it involves low energy scales. Hadronic contribution (had1) However, by dispersion theory, this a  (had1) can be related to measured in e + e - collisions. or τ decay.

30 Cannot be calculated from pQCD alone because it involves low energy scales. Hadronic contribution (had1) However, by dispersion theory, this a  (had1) can be related to measured in e + e - collisions or τ decay (assuming CVC).

31 Evaluation of R M. Davier et al., hep-ph/0208177.v3

32 Evaluation of R M. Davier et al., hep-ph/0208177.v3

33 Difference between e + e - and  M. Davier et al., hep-ph/0208177.v3

34 a μ (had1,e + e - )=(685±7)×10 -10 a μ (had1,τ) =(709±6)×10 -10 e + e - based τ based CorrectCorrect τ-data interpr. wrong Correct Wrong Wrong * Correct Wrong * Wrong T. Blum, hep-lat/0212018 *Other (e + e - ) collaborations are looking into it see, e.g., the KLOE Collaboration, hep-ex/0210013 a μ (exp)- a μ (SM, e + e - )=33.7(11)×10 -10 a μ (exp) -a μ (SM, τ) = 9.4(11)×10 -10 M. Davier et al., hep-ph/0208177.v3 Why?

35 a μ (had1,e + e - )=(685±7)×10 -10 a μ (had1,τ) =(709±6)×10 -10 e + e - based τ based CorrectCorrect τ-data interpr. wrong Correct Wrong Wrong * Correct Wrong * Wrong T. Blum, hep-lat/0212018 *Other (e + e - ) collaborations are looking into it see, e.g., the KLOE Collaboration, hep-ex/0210013 a μ (exp)- a μ (SM, e + e - )=33.7(11)×10 -10 a μ (exp) -a μ (SM, τ) = 9.4(11)×10 -10

36 a μ (had1,e + e - )=(685±7)×10 -10 a μ (had1,τ) =(709±6)×10 -10 e + e - based τ based CorrectCorrect τ-data interpr. wrong Correct Wrong Wrong * Correct Wrong * Wrong T. Blum, hep-lat/0212018 *Other (e + e - ) collaborations are looking into it see, e.g., the KLOE Collaboration, hep-ex/0210013 a μ (exp)- a μ (SM, e + e - )=33.7(11)×10 -10 a μ (exp)- a μ (SM, τ) = 9.4(11)×10 -10

37 Beyond standard model, e.g. SUSY W. Marciano, J. Phys. G29 (2003) 225

38 WMAPing out Supersymmetric Dark Matter and Phenomenology A.B. Lahanas and D.V. Nanopoulos, hep-ph/0303130 Figure 1: Cosmologically allowed regions of the relic density for tanβ=40 in the (M 1/2, m 0 ) plane. The mass of the top is taken 175 GeV. In the dark green shaded area 0.094<Ω x h 2 <0.129. In the light green shaded area 0.129<Ω x h 2 <0.180. The solid red lines mark the region within which the supersymmetric contribution to the anomalous magnetic moment of the muon is The dashed red line is the boundary of the region of which the lower bound is moved to its 2σ limit. The dashed-dotted blue lines are the boundaries of the region 113.5 GeV  m Higgs  117.0 GeV. The cyan shaded region is excluded due to b → s γ constrain.

39 Supersymmetric Dark Matter in Light of WMAP J. Ellis, K.A. Olive, Y. Santoso, and V.C. Spanos, hep-ph/0303043 Figure 2: The strips display the regions of the (m 1/2, m 0 ) plane that are compatible with 0.094 0 and tanβ = 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55. The parts of the strips compatible with g μ -2 at the 2-σ level have darker shading.

40 Precision measurements and “New Physics” W. Marciano, J. Phys. G29 (2003) 225 Electroweak physics: α -1 =137.035 998 77(40) G μ =1.16637(1)×10 -5 GeV -2 m z =91.1875(21) GeV m w =80.451(33) GeV Sin 2 θ w (m z )=0.23085(21) m t ≈174.3±5.1 GeV Δα Had =0.02761 Global fits: Experimentally: Δα Had ≈0.02752 (new e + e - data) Δα Had ≈0.02780 (new τ data)

41 Precision measurements and “New Physics” W. Marciano, J. Phys. G29 (2003) 225 Electroweak physics: α -1 =137.035 998 77(40) G μ =1.16637(1)×10 -5 GeV -2 m z =91.1875(21) GeV m w =80.451(33) GeV Sin 2 θ w (m z )=0.23085(21) m t ≈174.3±5.1 GeV Δα Had =0.02761 Global fits: Experimentally: Δα Had ≈0.02752 (new e + e - data) Δα Had ≈0.02780 (new τ data)

42 Precision measurements and “New Physics” W. Marciano, J. Phys. G29 (2003) 225 Electroweak physics: α -1 =137.035 998 77(40) G μ =1.16637(1)×10 -5 GeV -2 m z =91.1875(21) GeV m w =80.451(33) GeV Sin 2 θ w (m z )=0.23085(21) m t ≈174.3±5.1 GeV Δα Had =0.02761 Global fits: Experimentally: Δα Had ≈0.02752 (new e + e - data) Δα Had ≈0.02780 (new τ data)

43 Present In 2001 we have collected 3.7 Billion electrons with E>1.8GeV from a run with negative muons (μ - ). Run at n=0.122 and n=0.142. The analysis is going very well.

44 Present In 2001 we have collected 3.7 Billion electrons with E>1.8GeV from a run with negative muons (μ - ). Run at n=0.122 and n=0.142. The analysis is going very well. n=0.122 n=0.142 f g-2 ≈229 KHz f cbo ≈419 KHz f g-2 ≈229 KHz f cbo ≈491 KHz

45 Muon and Deuteron Electric Dipole Moments in Storage Rings Revolutionary New Way of Probing EDMs. What’s next…

46 Muon and Deuteron Electric Dipole Moments in Storage Rings Revolutionary New Way of Probing EDMs. What’s next…

47 Muon and Deuteron Electric Dipole Moments in Storage Rings Forefront of SUSY Search What’s next…

48 Muon Electric Dipole Moment at the 10 -24 e. cm Level It is Muon’s other (than g-2) Interesting Parameter It Probes SUSY (SM Predicted Value ~10 -35 e. cm) It Violates CP; Could explain the Baryon- Antibaryon Asymmetry in Universe

49 Spin Precession in g-2 Ring (Top View) 

50 Spin Precession in EDM Ring (Top View) 

51 The muon spin precesses vertically (Side View)

52

53 Radial E-field to Cancel the g-2 Precession Radial E-Field: The method works well for particles with small a

54 Radial E-field to Cancel the g-2 Precession Radial E-Field: The method works well for particles with small a

55 Parameter Values of Muon EDM Experiment Radial E-Field: E=2MV/m Dipole B-field: B~0.25T Muon Momentum: Need NP 2 =10 16 for 10 -24 e. cm. Muon EDM LOI: (http://www.bnl.gov/edm) to J-PARC, <one year of running.

56 Muon EDM Letter of Intent to JPARC/Japan, 2003

57 Deuteron EDM to <1  10 -25 e cm Sensitivity Level a=-0.143, B~0.25T, β~0.2 The Best EDM Limit for T-odd Nuclear Forces (Khriplovich). It Improves the Current Proton EDM Limit by a Factor of >1000. Statistical Sensitivity ~10 -26 e cm for 10 7 s.

58 Summary: a μ (exp)=11 659 203(8)×10 -10 (0.7 ppm) from 2000 run. Have 3.7 Billion electrons with E>1.8GeV from the 2001 run (μ - ). Run at different n-values: n=0.122 and 0.142. Analysis is going very well. There is a lot of effort to reconcile the e + e - and τ data. Many e + e - collaborations are going to check the a μ (had1) (using radiative return). Calculate a μ (had1) on the Lattice.

59 Sensitive Muon and Deuteron Electric Dipole Moment Searches in Storage Rings Revolutionary New Way of Probing EDMs. Exciting Physics …Summary

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