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La misura di : status e prospettive per le B factories. Marco Zito DAPNIA CEA-Saclay. Outline. Introduction sin(2 +) with BD (*) B->DK Conclusions. IFAE 04, 14-16 Aprile 2004, Torino. *. V td V tb. *. V ud V ub. *. V cd V cb. CP Violation in Standard Model.
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La misura di : status e prospettiveper le B factories Marco Zito DAPNIA CEA-Saclay Outline • Introduction • sin(2+) with BD(*) • B->DK • Conclusions IFAE 04, 14-16 Aprile 2004, Torino Marco Zito IFAE 04, Torino
* VtdVtb * VudVub * VcdVcb CP Violation in Standard Model Standard Model with 3 generations accommodates CP violation through a phase in CKM matrix Unitarity of the CKM Matrix Aim of B factories : Measure precisely the angles and the sides to overconstrain the unitarity triangle. Test of the SM in the CP violating sector a/f2 g/f3 b/f1 Marco Zito IFAE 04, Torino
Current Constraints on the CKM Angles World Averagesin2b = 0.736 ± 0.049 95% CL intervals with CKM Fitter: Direct measurement of g is a crucial step in the B factory program! Method in A. Hoecker et al, Eur. Phys. Jour. C21 (2001) 225, [hep-ph/0104062] Marco Zito IFAE 04, Torino
* VtdVtb * VudVub * VcdVcb Why measuring is difficult ? In the Wolfenstein phase convention, is the angle between Vub and Vcb. The ratio Vub/Vcb enters all interference terms sensitive to : small asymmetry or few events ! a/f2 g/f3 b/f1 • Strategies : • BD(*) Small asymmetry : partial + full reconstruction • B->DK : (GLW) Small asymmetry : many modes • B->DK (ADS) Large asymmetry : few events • B->DK Dalitz plot analysis • B->K difficult theory uncertainties ! (not covered in this talk) Marco Zito IFAE 04, Torino
Measurement of sin(2b+g) in B0D(*)p Favored amplitude Suppressed amplitude through b u transition Strong phase difference • CP violation from interference of mixing (weak phase= 2b) and decay (weak phase ) interference terms measures sin(2b+g) • Theoretically clean : no penguin contribution, strong phase measurable • Small time dependentasymmetry (o(4%)) • r is an external input CKM angle B0 mixing f B0 Marco Zito IFAE 04, Torino
B0D(*)p Time-dependent decay rate distributions - K+ -s Tag B K+ U(4s) Reco B z + Dt @Dz/gbc Dz • Measurement of S and S determine 2b+g and d • Using Dp and D*p removes some ambiguities Marco Zito IFAE 04, Torino 4 ambiguities on 2b+g
D*- +f B0 D0 -s X B0D(*)p :partial reconstruction (BaBar) • Use only the fast and soft pion tracks : no D° reconstruction ! F E(F)~.5 mB • Combine the fast pion (2.1<p<2.4 GeV/c) with a slow pion (p<250 MeV). • Compute the mass Mmiss of the recoiling object (r.m.s. 3 MeV) 1 rad S P(s-)<250 MeV D0 The unreconstructed D0 complicates vertexing and tagging Most of the D0 decay product inside this cone Marco Zito IFAE 04, Torino
B0D(*)p :the BaBar event sample B invariant mass Exclusive reconstruction(ER) : N(D)=5200 N(D*)=4700 BaBar Based on a 81 fb-1 sample Partial reconstruction(PR) : N(D*)=6400 (lepton tag) N(D*)=25100 (kaon tag) Kaon tagged Lepton tagged signal combinatoric BaBar Continuum Marco Zito IFAE 04, Torino
Lepton tags B0D(*)p :BaBar results BaBar CP asymmetry 2 r* sin(2β+γ) cos(δ*)sin(m t) Lepton tagged Kaon tagged BaBar t(ps) t(ps) t(ps) PRELIMINARY hep-ex/0309017 hep-ex/0310037 Mixing asymmetry 2.3 significance ! 2 r* sin(2β+γ) cos(δ*) = -0.063 ± 0.024 (stat.) ± 0.014 (syst.) PR 2 r* sin(2β+γ) cos(δ*) = -0.068 ± 0.038 (stat.) ± 0.020 (syst.) ER 2 r sin(2β+γ) cos(δ) = -0.022 ± 0.038 (stat.) ± 0.020 (syst.) ER Used as a cross-check There is also a Belle result with excl. Reco. hep-ex/0308048 Marco Zito IFAE 04, Torino
B0D(*)p :Interpretation • Need the value of r(*) to interpret the results in terms of sin(2β+γ) • Use (I. Dunietz, PLB 427,179 (1988)) the measured (BaBar+Belle) Br(BD(*)s) + SU(3) + decays constants to get • r=0.019 0.004 and r*=0.017+0.005 -0.007 • Derive the combined confidence level as a function of sin(2β+γ) using the Feldman-Cousins method with toy MC • |sin(2β+γ)|>0.87 (68% CL) • |sin(2β+γ)|>0.58 (95% CL) • With a similar method limits on |sin(2β+γ)| versus r* are produced CL(%) |sin(2β+γ)| Marco Zito IFAE 04, Torino
Constraints on the Unitarity Triangle from BaBar • Despite limited statistics already interesting constraint ! • Complementary to • Excludes two sin(2) branches • Start constraining the triangle only with CP violation in the B sector ! Using sin(2), sin(2+) and cos(2) Thanks to Ch. Yeche Marco Zito IFAE 04, Torino
g b u D0 c B+ s K+ u u g with B- D0K- decays Suppressed amplitude: b u transition Color suppression Favored amplitude s K+ u b c B+ D0 u u • Interference (and direct CP violation) may occur if D° and D° decay in the same final state f : • f can be CP eigenstate (+-, K+K-, Ks° …)Gronau, London, Wyler (GWL) method • f =DCSD for D° (K+-) and CFD for D° (K+-) Atwood, Dunietz, Soni (ADS) • or f=3 body final state : Dalitz plot analysis (Giri, Grossman, Soffer, Zupan) DCSD : Doubly Cabibbo Suppressed Decay CFD : Cabibbo Favoured Decay Marco Zito IFAE 04, Torino
GLW method Hep-ex/0311032 82 fb-1 BaBar Flavor modes (K,K3,K°) D°K D° • Measure A and R and solve for r,, • Four observables and three unknowns • Based on o(20) ev. for the CP eigenstate modes • Analysis of CP=- modes by BaBar in progress • No constraint on yet CP=+ modes (K+K-,+-) D°K D° E(GeV) Marco Zito IFAE 04, Torino
ADS method BaBar • ADS method : Measure B+ [K-+]DK+ • Only O(5-20) DCSD events expected • Requires powerful background rejection • Use favored modes as control sample • N (B+ [K-+]DK+) = 1.13.0 (DCSD) • vs 261 22 (CFD) • rB<0.22 (90% CL) • Excludes most favorable scenario for the sensitivity of this method DCSD 109 fb-1 CFD Ratio DCS/CF Marco Zito IFAE 04, Torino rB
GLW-ADS method : expected sensitivity GLW +ADS(K) +CLEO-c GLW GLW +ADS(K) 2 • Toy MC with 500 fb-1 • Strong dependence on r • Prospect not so bright for r=0.1 rb=0.1 1 2 3 rb=0.2 2 Study by C. Campagnari et al. Marco Zito IFAE 04, Torino
Belle: Dalitz plot method-1 Hep-ex/0308043 Belle • Proposed by Giri et al. (hep-ph/0303187) • Uses Cabibbo-allowed mode Ks+ - • The Dalitz plot amplitude can be written as • Where |f|2 can be fitted in D* tagged D° decays (57800 evt !!) and r, and are fitted in the Dalitz plot of B- D0K- decays • B- D0- is used as a control sample m2(Ks-) NB: this is data ! m2(Ks+) m2(Ks+) m2(+-) MC: Slices of Dalitz plot B invariant mass B+ B- Marco Zito IFAE 04, Torino 107 signal ev. are selected on 140 fb-1 m2(Ks-) m2(Ks+)
Belle: Dalitz plot method-2 Dalitz plot projection • B+→D0K+and B+→D*°K+, D°→Ksπ+π- • =φ3=81°±19°±13°(syst)±11°(model) from combined fit, r=0.31±0.11 • 95% CL interval from combined fit: 35°<φ3<127° • Caveat : • model dependence of Dalitz amplitude • Unexpectedly large value of r (r=0.13 exp.) r=0 m2(Ks-) m2(Ks+) Belle 95% CL r A. Poluektov at Moriond EW 2004 Marco Zito IFAE 04, Torino
Outlook • BaBar : 200 fb-1 expected by summer 2004, 500 fb-1 by 2006 • sin(2+) : add new modes like D, D* • B- D°K : add many modes : drops in the bucket concept • Dalitz plot analysis : r value ? Model independent approach Marco Zito IFAE 04, Torino
Conclusions • First measurements of sin(2+) and are available for CKM fitters ! • Many more methods and modes currently explored mainly B DK • Already interesting constraints in the - plane • The rapid increase of luminosity will be extremely beneficial to these difficult measurements • Improved and complementary measurements of in 2004-2005 at the B-factories experiments Marco Zito IFAE 04, Torino
B0D(*)p : Full result list 2 r* sin(2β+γ) cos(δ*) = -0.063 ± 0.024 (stat.) ± 0.014 (syst.) PR 2 r* cos(2β+γ) sin(δ*) = -0.004 ± 0.037 (stat.) ± 0.020 (syst.) PR 2 r* sin(2β+γ) cos(δ*) = -0.068 ± 0.038 (stat.) ± 0.020 (syst.) ER 2 r* sin(2β+γ) cos(δ*) = 0.031 ± 0.070 (stat.) ± 0.033 (syst.) ER 2 r sin(2β+γ) cos(δ) = -0.022 ± 0.038 (stat.) ± 0.020 (syst.) ER 2 r cos(2β+γ) sin(δ) = -0.025 ± 0.068 (stat.) ± 0.033 (syst.) ER Marco Zito IFAE 04, Torino
B0D(*)p :CP violation on the tag side for kaon tagged events Due to presence of Doubly Cabibbo Suppressed Decays on the tag side We introduce r’ and δ’ in the coefficients relevant to the sin(Δm.t) term ABC parametrization* to restrict the set of fit variables to 3 a = 2 r sin(2β+γ) cos(δ) b = 2 r’ sin(2β+γ) cos(δ’) c = 2 cos(2β+γ) (r sin(δ) – r’ sin(δ’) * : O. Long, M. Baak, R.N. Cahn, and D. Kirkby, SLAC-PUB-9687, hep-ex/0303030 Marco Zito IFAE 04, Torino
d sin(2b+g) in B0 D(*)0K(*)0 Al3(r-ih)e-ig Al2 c u b b D(*)0 u c B0 B0 l s s K(*)0 d d d Strong phase difference • Similar to D(*)p: interference between decay and mixing, but… • Advantages: • Much larger asymmetries: • CP violation from tag-side not significant • Disadvantages: • Color suppressed decays: Smaller branching fractions • Possible competing effects from Doubly-Cabibbo-suppressed D0 decays • Requires tagging for time-dependent studies: 70% tagging efficiency Measure r with K*0K-p+ Marco Zito IFAE 04, Torino Kayser, London, PRD 61, 116013 Atwood, Soni, hep-ph/0206045
D0K0 D0K*0 Current measurements and limits in B0 D(*)0K(*)0 81 fb-1 78 fb-1 Peaking background D0 sideband Combinatoric Vub Vub contribution necessary for measurement of g not observed yet! Marco Zito IFAE 04, Torino
g in Charmless B PP,PV decays g P T • Tree amplitude suppressed in Standard Model • Penguin contributions large: • Interference between Tree and Penguin • Main Challenges • Background suppression • Contribution of EW penguins • Effects of Final State Interaction • Requires estimate of |P/T| Possible window on New Physics 5% if neglecting penguins Branching fractions and CPasymmetries sensitive to g ACP alone not sufficient Need also BF to have ahandle on d Marco Zito IFAE 04, Torino