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1 g-2 phase study from GEANT simulation Qinzeng Peng Advisor: James Miller Boston University Sep 28, 2004 Muon g-2 collaboration at BU: Lee Roberts, Rober Carey, Jon Paley, Xiaobo Huang Institutes: BU, BNL, UIUC, Univ. of Minnesota, Yale Univ.
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2 Outline I. Brief introduction to g-2 II. Experimental set up and simulation III. Simulation results and analysis
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3 What is g-2? magnetic momentgyromagnetic ratiospin Dirac equation predicts g=2 in nature radiative correction makes g≠2 a μ (SM) = a μ (QED) + a μ (hadronic) + a μ (weak) a μ (New Physics) = a μ (Measured) − a μ (SM) where Studied Muon instead of Electron due to
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4 Inflector Kicker Modules Storage ring Ideal orbit Injection orbit Pions Target Protons (from AGS)p=3.1GeV/c Experimental Setup – Muon storage Polarization Momentum Muon polarization Muon storage ring injection & kicking focus by Quadrupoles R=711.2cm d=9cm (1.45T) Electric Quadrupoles
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5 spin precession and muon decay muons move in circle with constant speed spin precession (Thomas + Larmor) electrons decay mostly along the spin direction and boosted by P muon fitting by 5-parameter function to get N(t,E) = N 0 (E)e -t/τ (1+A(E)Cos(ω a t+Φ(E)) DET magic γ= 29.3
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6 Phase shift on ω a uncertainty What if φ is not a constant? Take an example: if And measuring time is about 600 μs, then
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7 g2Geant simulation Inflector Ideal orbit p≈3.1GeV/c DET Beam-line simulation g2Track g2GEANT Simulates nearly all geometric set up in the storage ring Inflection Kicking scraping Jon Paley Hugh Brown Robert Carey Muons generation Spin polarization
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8 Beam-line / Calorimeter alignment vertical horizontal Radial in Beam Radial on DET Vert. in Beam Vert. on DET Beam in the ring Calorimeter t decay -t measure =drift time
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9 Data selection Energy cut : En >1.8GeV Energy cut : En >1.8GeV Detector dependence : average over 24 detectors Detector dependence : average over 24 detectors Drift time : offset of g-2 phase Drift time : offset of g-2 phase
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10 Beam Ф vs. detector vertical position Symmetric about center Energy dependent ΔΦ big : -80 ~ +80 mrad Φ(all) small : about 5 mrad Φ change sign at 3cm 3cm DET ypc1
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11 outward and inward decay outward < 0 Φ < 0 dt longer inward > 0 Φ > 0 dt shorter 3cm outward inward
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12 Ф vs. detector radial position ΔΦ smaller, 30 mrad Φ ≈0 on outside Φ >0 on detector
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13 Ф vs. beam vertical/radial position symmetric about center of beam ΔΦ big Φ ≈0 at center ΔΦ smaller Φ ≈0 on inside Φ >0
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14 Beam vertical shift ΔΦ ≈0 Φ is detector dependent, 4 groups --- 4 Quads
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15 Beam width change idea: change beam vertical distribution by a weighting factor Result : 1 percent width change / 0.1 mrad phase shift
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16 Beam upper cut – muon losses Muon losses: 1.64% ΔΦ = -0.323 mrad 9cm
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17 Detector gain shift very small effect 10% gain shift / ΔΦ = 0.014 mrad DET Vert. E 1.05 E 0.95 E
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18 Beam / detector vertical alignment 0.9mm/1.0mm shift 0.11%/1.0% width change
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19 CBO modulation Betatron Oscillation Betatron Oscillation Combine 23 detectors in one CBO period Combine 23 detectors in one CBO period Time = MOD ( time - DET# /24*Tcbo, Tcbo) Coherent Betatron Oscillation Coherent Betatron Oscillation
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20 Sampling T cbo =2.4μs
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21 Combine 23 detectors CBO effect
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22 CBO modulation Number modulation Asymetry modulation, 0.22%
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23 phase modulation, 0.358 mrad dt modulation, 0.175 mrad
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24 conclusions Simulation results consistent with Real data, like FSD studies. Simulation results consistent with Real data, like FSD studies. Phase shift due to the geometric set up is a small effect on ω a. Phase shift due to the geometric set up is a small effect on ω a. CBO effect is a small effect. CBO effect is a small effect.
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