Lake Louise Winter Institute Outlook: Introduction LHCb performance Radiative decays: CP violation Bs Φγ Backward-forward Asymmetry B K * μμ Branching ratio of very rare Bs μμ Conclusions Prospects for rare B decays in LHCb Jose A. Hernando (CERN, on leave Universidade de Santiago de Compostela, Spain) [On behalf of the LHCb collaboration]
Lake Louise Winter Institute LHCb experiment and conditions Luminosity range cm -2 s -1 Nominal integrated luminosity 2 fb -1 / year (10 7 s) bb produced/year B, Bs, B + But large backgrounds and small BR 0(10 -6 )of relevant decays 10 MHz visible interaction (1% bb) Total10 fb -1 P. Vazquez
Lake Louise Winter Institute Rare B decays LHCb Physics CP violation in B system: using tree and penguins processes (NP) Rare B decays: test FCNC (b s) V. Gligorov Rare B decays FCNC has a pivotal roll: They are suppressed in SM, only realized via boxes or penguins NP can show up as the same level of SM Present results (i.e. b sγ) strongly limit extensions of SM Indirect search of new particles: “visible” via loops Experimental observables: ratios, asymmetries, branching ratios to leptons b sγ Radiative decays: B K*γ, Bs Φγ Λ b Λγ, Λ b Λ * γ B ρ 0 γ, B ωγ b sll : B K*μμ, B + K + μμ, B + K + ee B q ll Bs μμ LFV B q ll’ Bs μe A CP (t) (Bs Φ γ) A FB (B K * μμ) β(Bs μμ)
Lake Louise Winter Institute Bs Φ γ Motivation: Inclusive BR in agreement with SM LHCb can perform exclusive measurements And test the γ polarization In SM is b sγ is predominantly (at 0(m s /m b ) left handed CP violation in the mixing and decay depends on the γ polarization Measured in B K*(K s π 0 )γ A CP at Belle[3], BaBar (S K*γ = ±0.31±0.05) [4] LHCb can measure time-dependent CP asymmetry of Bs Φ γ [1]NNLO [2]HFAG [1] hep-ph/ [2] arXiv/ hep/ex [3] hep-ph/ , Phys.Rev D72, [4] arXiv/ hep/exp [5] hep-ph/ [ 5] SM: C~0, S~-0.1±0.1%, A Δ ~ sin2ψ Ψ fraction of “wrong” polarization A CP (t) (Bs Φ γ)
Lake Louise Winter Institute A CP (t) for B s Φ γ Full detector simulation main background bb (37 M) Selection Et(γ) > 2.8 GeV, Yields (2 fb -1 ): Total efficiency ~ 0.3% Background bb inclusive: B/S ~ 90 CL Issues: Acceptance function a(t) σ(t) as function of topology MC stats: 37 M bb events 2 fb -1 σ(A Δ )0.20 σ(S,C) fb -1 B K*γ 72 k Bs Φ γ 11 k
Lake Louise Winter Institute A FB (B K * μμ) Motivation: BR in agreement with SM β(B K*μμ) But NP can show us in angular distributions A FB asymmetry vs m 2 μμ Decay described with 3 angles (θ l,Φ,θ K* ) A FB of μ in θ l vs m 2 μμ SM zero point well predicted: SM: [1] GeV 2 BaBar and Belle [2] Measurements [1] hep-ph/ [2] hep-ph/ A FB M 2 (GeV 2 ) BELLE ’06 m 2 [GeV 2 ] A FB (m 2 μμ ) theory illustration
Lake Louise Winter Institute A FB (B K * μμ) Yields Efficiency ~ 1% Background B/S 90% CL bb: b μ,b μ bb: b μ,c (c μ) Issues Acceptance function a(θ l,m 2 μμ, ) Sensitivity 0.07 fb -1 competitive with BaBar & Belle An example 0.5fb -1 experiment An example 0.1fb -1 experiment M 2 (GeV 2 ) A FB 2 fb -1 B K*μμ 7.3 k 0.5 fb -1 2 fb fb -1 σ(s0)0.8 GeV GeV GeV 2
Lake Louise Winter Institute β(Bs μμ) Motivation Bs μμ very rare Helicity suppress (m μ /m B ) 2 SM well predicted SM: β(Bs μμ) = (3.55±0.33) x Very sensitive to (pseudo) scalar operators MSSM ~ tan 6 β/M 4 A MSSM (NUHM) fit favor large tanβ ~ 30 μ g-2 results (deviate from SM 3.4 σ) Current limits [2] CDF BR < % 2fb -1 [3] D0 BR < % CL [1] arXiv: v1 [hep-ph] [2] arXiv: v1 [hep-ex] [3] arXiv: v1 [hep-ex] [1]
Lake Louise Winter Institute β(Bs μμ) Small signal and large background, but Efficient trigger: ~1.5 kHz inclusive μ. Di-μ Mass resolution: σ ~20 MeV Vertexing: GL: Combine geometrical variables Background: Main background (b μ,b μ, b μ, b c μ ) B hh, small compared with b μ,b μ Bc + J/Ψμν dominant of exclusive, but still small Analysis: Divide (GL, Mass) space in N bins Expected events/bin for signal, signal+bkg Yield : Total efficiency ~10% (all GL values) S ~30 events, Bkg ~ 2fb -1 (GL>0.5) Control channels: Signal description: B hh ~200 2fb -1 background (from sidebands) Normalization: B + J/Ψ K + 2 2fb -1 Red: signal Blue: bb inc. Black: b μb μ Green: Bc+ J/Ψμν GL (geometry) Mass (MeV) Bs μμ Bs KK arbitrary units
Lake Louise Winter Institute x10 -8 (~0.05 fb -1 ) 5x10 -9 (~ 0.4 fb -1 ) Integrated luminosity (fb –1 ) BR (x10 –9 ) Uncertainty in background prediction Expected final CDF+D0 limit SM prediction 90% CL imit on BR (only bkg is observed) [1] arXiv: v1 SM agreement 2 fb –1 3 evidence 6 fb –1 5 observation Exclusion: 0.1 fb –1 BR < fb –1 < SM β(Bs μμ) [1]
Lake Louise Winter Institute Conclusions LHCb finishing installation, getting ready for 1 st collisions Rare B decays in LHCb will constrain extensions of SM or find NP Already with first “year” data 0.1, 0.5 fb -1 Bs μμ excluded at SM value with 0.5 fb -1 A FB (B K*μμ) σ(s 0 ) ~0.8 GeV 0.5 fb -1 And above 2 fb-1 Bs μμ evidence if SM 2 fb -1, observation 6 fb -1 B K * μμ σ(s 0 ) ~0.5 (0.3) GeV 2 (10) fb -1 other observables: A (2) T, F L Bs Φ γ A CP asymmetry >2 fb -1
Lake Louise Winter Institute Particle ID π-K separation: Kaon ID ~ 88% Pion mis-ID ~ 3% μ ID B q hh (~0.5%) 2 (mu-ID eff 95%) LHCb expected performance Mass resolution Vertexing σ(Mass) Bs μμ ~20 MeV B K*μμ ~14 MeV Bs Φ γ ~90 MeV σ(proper time) Bs Φ γ ~ fs Trigger: L0 2 HLT B signature : “large” Pt and displaced tracks HLT: ~ 1.5 kHz μ + di-μ inclusive sample efficiency (L0xHLT) Bs μμ ~90 % B K* μμ ~70 % B Φγ ~40 % P. Vazquez
Lake Louise Winter Institute A (2) T,F T (B K*μμ) Other observables [1] in B K*μμ Expresed in terms of transversity amplitudes Fit individual angular distributions (θ l,Φ,θ K* ) vs m 2 μμ 2 fb -1 Asymmetry A T (2) Longitudinal polarization F L SM NLO MSSM tan =5 2 fb –1 10 fb –1 A T (2) 0.42 0.16 FLFL A FB Sensitivity with [1] hep-ph/ An example 2 fb -1 experiment