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CP Violation lectures Measurement of the time dependence of B0B0bar oscillation using inclusive dilepton events [BABAR-CONF-00/10] G. Cerminara
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Outline The Goal of the measurement How to carry on the measurement
What they wanted to measure Why to measure B0B0bar oscillation How to carry on the measurement B flavor tagging through lepton sign Time evolution measurement Experimental challenges Lepton identification and dileptons event selection Background rejection Dz measurement Results and systematic uncertainties The fit to data Results
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Outline The Goal of the measurement How to carry on the measurement
What they wanted to measure Why to measure B0B0bar oscillation How to carry on the measurement B flavor tagging through lepton sign Time evolution measurement Experimental challenges Lepton identification and dileptons event selection Background rejection Dz measurement Results and systematic uncertainties The fit to data Results
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Why to measure B0B0bar oscillations
B0B0bar oscillation frequency is sensitive to CKM matrix element |Vtd| Gives stringent constraint on Unitarity Triangle (together with BsBsbar oscillation frequency) B0 B0bar b bbar dbar d (u, c), t ~ VtbVtd mt2/mW2 Dm
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What they Measured In order to measure DmB0 between the two mass eigenstates we must estimate: Therefore we want to measure the time dependent asymmetry Dt = difference between two decay times of the B mesons Rate( BB Same b flavor ) Rate( BB Opposite b flavor ) DmB0 (t) (1) Opposite b flavor Same b flavor (2)
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Outline The Goal of the measurement How to carry on the measurement
What they wanted to measure Why to measure B0B0bar oscillation How to carry on the measurement B flavor tagging through lepton sign Time evolution measurement Experimental challenges Lepton identification and dileptons event selection Background rejection Dz measurement Results and systematic uncertainties The fit to data Results
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Basic Idea (I) To carry on this measurement we must:
Tag the B meson flavor Measure the flavor of the BB mesons as a function of time 1) Use lepton to tag the B meson flavor The sign of the lepton determines the flavor of the B meson BR ( B0 ℓ+n + anything) ~ 10 % BR ( B0bar ℓ-n + anything) ~ 10 % With ℓ = e and m The time dependent asymmetry becomes: Inclusive reconstruction in order to have high reconstruction efficiency (3)
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Basic Idea (II) 2) Use PEP-II asymmetric B factory for time-dependent measurement PEP-II asymmetric e+e- collider: e+: p = 3.1 GeV e-: p = 9.0 GeV CM of (4s) has a boost along the beam axis BBbar almost at rest in (4s) CM but boosted along the beam axis (z) (4s) BBbar <bg> = 0.554 It is possible to measure the proper decay time of the B mesons measuring their decay length We can therefore compute Dt measuring Dz !!! e- e+ (4s) (4s) (4s) Dz { B0 B0bar
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Sketch diagram of the measurement
Bbbar produced by (4s) decay: e+e- (4s) BBbar e- e+ (4s) Z axis (beam)
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Sketch diagram of the measurement
Bbbar produced by (4s) decay: e+e- (4s) BBbar e- e+ (4s) B0 Z axis (beam) B0bar
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Sketch diagram of the measurement
Bbbar produced by (4s) decay: e+e- (4s) BBbar B decay semileptonically B ℓ + n + X ℓ+ e- e+ (4s) B0 Z axis (beam) B0bar ℓ-
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Sketch diagram of the measurement
Bbbar produced by (4s) decay: e+e- (4s) BBbar B decay semileptonically B ℓ + n + X Leptons are inclusively reconstructed The lepton sign used for flavor tagging Track extrapolated to point of closest approach to the beam axis Dz measured as z difference of positions of closest approach compute Dt ℓ+ e- e+ (4s) B0 Dz Z axis (beam) B0bar ℓ-
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Outline The Goal of the measurement How to carry on the measurement
What they wanted to measure Why to measure B0B0bar oscillation How to carry on the measurement B flavor tagging through lepton sign Time evolution measurement Experimental challenges Lepton identification and dileptons event selection Background rejection Dz measurement Results and systematic uncertainties The fit to data Results
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The BaBAR Detector Quick overview of main Babar subdetectors (from in to out): SVT: Silicon Vertex Detector DCH: Drift Chamber Charged particle detection Momentum measurement DIRC: Cherenkov Radiation Detector Particle identification EMC: Electromagnetic Calorimeter Photon detection Pion/electron separation IFR: Instrumented Flux Return Return Yoke instrumented with RPCs Muon identification (rejection of long life particles)
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Lepton Identification
Selection of dilepton events, basic ingredients are: Lepton (e, m) identification Electrons: Specific requirement on ratio: Energy in the EMC/Momentum in DCH Lateral shape of energy deposition in the Calorimeter (EMC) Ionization density in the DCH Muons: Energy released in the calorimeter Compatible with Minimum Ionizing Particle Reconstruction in the IFR Track continuity and penetration depth Efficiencies are monitored with reference samples: Main sources of contamination are p0 and p+/- (~0.3% and ~3% respectively) Electrons Muons Efficiency 92 % 75 %
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Background Rejection (I)
Non BB background rejection (Continuum Rejection) Fox-Wolfram ratio (R2) requirement: The Fox-Wolfram momentum of order lth is defined as: Momentum-weighted sum of Legendre polynomial of the lth order computed from the cosine of the angle between all pairs of tracks: [G.C. Fox and S. Wolfram, Nucl. Phys. B149 (1979) 413] The Ratio R2 is defined as: Directional events (Continuum like) have higher R2 than spherical BBbar events: Requirement: R2 < 0.4 (4) (5)
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Background Rejection (II)
Rejection of two-photon events (gg ℓ + ℓ -) Squared Invariant mass of the event > 20 (GeV/c2)2 Number of charged tracks > 4 Rejection of lepton pairs from J/y decay (J/y ℓ + ℓ -): M(ℓ + ℓ - ) < M(J/y ) – 40 MeV and M(ℓ + ℓ - ) > M(J/y ) + 40 MeV
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Selection of Dilepton Events
Selection of direct dilepton events We want to distinguish between cascade leptons (b c l) and prompt leptons from B decay The selection is performed using a Neural Network combining 5 discrimination variables (in (4s) reference frame): Momenta of two leptons with highest momentum (p*1, p*2) Total visible energy and missing momentum (Etot, pmiss) Opening angle between the leptons q12
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Selection of Dilepton Events
More detail on some input variables: Powerful discrimination of cascade leptons Lepton momentum BBbar direct leptons (signal) Leptons from cascade
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Selection of Dilepton Events
More detail on some input variables: Angle between leptons Powerful discrimination of cascade leptons BBbar direct leptons (signal) Leptons from cascade
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Selection of Dilepton Events
More detail on some input variables: Difficult to discriminate between signal and background Missing momentum BBbar direct leptons (signal) Leptons from cascade
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Selection of Dilepton Events
The NN is trained with 40k events Dileptons from B0 and B+/- Output variable used to discriminate: 1 direct events (signal) 0 cascade events Require NN out > 0.8 Efficiency 9% Signal purity 78% NN Output Cascade Signal Cascade Signal
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Dz Measurement Determination of z coordinate of B decay vertex:
1st approximation: the z of the point of closest approach between lepton track and the beam spot in the transverse plane Further refinement: Use both lepton tracks to estimate the beam spot position in the transverse plane using beam spot constraint and a vertex fit. (Not really clear how…) Resolution on Dz: Estimated from MC data: Double gaussian fit: sn = 87 mm sw = 195 mm Cross check with real data (J/y ℓ + ℓ -) : 5% - 10% uncertainties on these values (one of major contribution to systematic uncertainties)
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From Dz measurement to Dt
The difference between the two decay times is: With <bg> = 0.554 No correction for B meson motion in (4s) reference system: In inclusive approach it is not possible to determine the B boost MC study shows that this effect is negligible compared to the level of accuracy of this analysis (6)
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Outline The Goal of the measurement How to carry on the measurement
What they wanted to measure Why to measure B0B0bar oscillation How to carry on the measurement B flavor tagging through lepton sign Time evolution measurement Experimental challenges Lepton identification and dileptons event selection Background rejection Dz measurement Results and systematic uncertainties The fit to data Results
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The Final Fit Value and error of DmB0 is extracted with c2 fit to dilepton asymmetry The fit function is: ƒOS and ƒSS contain contributions from mistagged events and depend on: DmB0, h0(mistag fraction), R (charged B fraction) and a (time dependence of h0). (Used as free parameters in the fit) Lifetimes fo charged and neutral B: G0, G+ (fixed to the world average values) (7) ƒreso = resolution function ƒother = time distribution for background events (cascade leptons and non-BBbar events) Estimated from off-resonance data OS: opposite sign SS: same sign
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The Final Fit Four parameter fit to data: Results:
Data collected after an integrated luminosity: L = 7.73 fb-1 (July 2000)
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Final result The result for DmB0 measurement is therefore:
Main sources for systematic uncertainties are: Lepton misidentification Time-dependence of the cascade events Resolution function of Dz
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Backup slides (I) Functions used in the fit:
Time distributions of mixed and unmixed events (explicit form) Time distributions of Opposite and Same sign events: Mistagged events
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