LHCb Physics reach

1. LHCb Physics reach Marco Musy Università di Milano Bicocca and INFN Milano LHC2003 International Symposium Fermilab, 3th May 2003 Fermilab 3th May 2003

2. Overconstrain the unitarity triangles • Search for New Physics beyond SM Ambitious physics goals of LHCb Precision CPV measurements, using also pure hadronic and multi-body final states (Bd pp, BdD*p, . . .) Exploit CPV in new decay channels as in Bs (BsKK, BsDsK, BsJ/yf , . . .) Rare b-decays (BdK* g, BdK*mm, Bsmm . . .) New particles may show up in loop diagrams, overconstrain will allow to disentangle SM components from the new-physics ones b b t High statistics is a requirement NP? d d t Fermilab 3th May 2003

3. BdJ/yKS BdD*p Bs mixing fNR  |Vub/lVcs| • If New Physics is there LHCb experiment can spot it in 2008 ! r r 2007 CPV from LHCb in one year |Vtd/Vts| sin 2b gand dgnotwell known |Vub/lVcs| 2008 LHCb 2007 h now Bdpp BdJ/yKS BsJ/yf BsDsK Fermilab 3th May 2003

4. Experimental challenge HIGH STATISTICS BdK*g BdJ/y r 0 • LHCb has to deal with a large variety of final states with different topologies • Hot pp environment needs a robust trigger sbb / sinel.~ 0.01 (sbb~ 500 mb), many particles are not associated to b-hadrons • b-hadrons do not evolve coherently • High bb yield, 1012/year of Bd, Bs , baryons, Bc with bgct ~ 7mm Fermilab 3th May 2003

5. LHCb detector Detector has undergone a reduction of material in front of RICH2 (60%  40% for X0, 20%  12% for lI) Less interactions in detector, Level-1 Trigger includes momentum measurement Technologies have not changed  September 2003: “Detector Reoptimization TDR” and “Trigger TDR” Construction phase is in good shape ( T. Nakada talk) Fermilab 3th May 2003

6. Fully simulated bb event in Geant3 • MC Pythia 6.2 tuned on CDF and UA5 data • Multiple pp interactions and spill-over effects included • Complete description of material from TDRs • Individual detector responses tuned on test beam results • Complete pattern recognition in reconstruction: MC true information is never used • 1M inclusive bb events produced in Summer 2002 • New “Spring” production ready: 10M events for September TDRs • Sensitivities quoted here are obtained by rescaling earlier studies to the new yields Fermilab 3th May 2003

7. RICH RICH-1 2<p<100 GeV/c <e(KK)>= 88% <e(K )>=2.7% Tracking • <Ntracks>= 27 “physics” tracks etrack~95% p>5 GeV/c “ghost” rate ~ 8% @pT>0.5GeV e, m PID <e(mm)>= 86% <e(ee )>= 78% <e( e,m)>=1% Main performances VELO PV: s~ 47 mm SV: s~170 mm VELO Bs mixing Measure Dms at 5s up to 48 ps-1  see dedicated talks! Fermilab 3th May 2003

8. eacc* e2track* ecut* eL0* eL1= 13% * (96%)2* 22% * 61% * 51% Event yielduntagged 1 year = 2 fb -1 L= 2x1032 cm–2s-1 Efficiency includes: • Geometrical acceptance, eacc including detection efficiency, material • Trigger efficiency: Level-0 && Level-1, eL0,1 including expected Pile-up rate veto • Reconstruction efficiency (tracking, calorimeters, PID),etrack • Selection cuts efficiency to reconstruct the final state and reject background, ecut norm. to 4p Fermilab 3th May 2003

9. p+ p- B0 B0 D K- l b B0 d b d p+ u u Flavour tagging Knowledge of flavour at birth is essential for the majority of CPV measurements Opposite side lepton tag ( b l ) Opposite side kaon tag ( b  c s ) - unique to LHCb, BTeV - correlated to hadron trigger Same side pion and kaon tag (with p coming either from B** or fragm. successfully used by CDF already) Vertex charge tagging • Only single particle tagging (e, m, K) from opposite side B decay used in this presentation e= 0.40,D = 0.40 eD2 = 6.4% • The new MC data give similar results Fermilab 3th May 2003

10. eeff Bs Opposite Side Flavour tagging K-tag Typical tagging efficiencies: in BsK p, KK, Dsp channels (after L0*L1 trigger, any nr of collisions) IP/s Bs Same Side K-tag Work is in progress to update and improve the efficiencies Fermilab 3th May 2003

11. B(s) pp,K p,K K min IP/s max pT Proper time s = 41 fs incl. bb • Selection cuts on Signal charged tracks, PID Reconstructed B signal 92% purity s=18 MeV/c2 pT(B) L/sL • Combinatorial bb bckgr, can be fully rejected even relaxing mass cut S/B ~ 1 Fermilab 3th May 2003

12. g from B(s) pp, K K(proposedby R. Fleischer ) • Relies on “U-spin” symmetry assumption (ds) which is the only source of theoretical uncertainty • Clean measurement of g assuming dg from Bs J/y f and bfrom B  J/y Ks • Sensitive to New Physics contribution which can be pointed out by comparing with g obtained from DsK Fermilab 3th May 2003

13. BS K+ K- B0  +- g from B(s) pp, K K input values Evaluation of and sensitivity from time-dependent measured asymmetry Fermilab 3th May 2003

14. g from B(s) pp, K K BS K+ K- increasing xs BS K+ K- CP asymmetry can be measured in Bs KK up to xs=40 with an error increase of a factor 1.6 For xs=20 s(g) ~ 3o New! tagging efficiency  In one year: B0  +- BS K+ K- Fermilab 3th May 2003

15. afrom B0 pp RICH PID and hadron trigger are fundamental Decay is polluted by penguin diagrams Penguin/Tree might be as high as 0.2 If |P/T| will be known to ±0.1 then 5°< s(a) < 10°(depending on parameter value) Fermilab 3th May 2003

16. , K Bs K K Ds  Bs Dsp,DsK 72k Ds 8k DsK • ~ 6.5 MeV/c2 s = 168 mm s = 418 mm Bs vtx resolution (mm) Ds vtx resolution (mm) Dsmass (GeV) When selectingBs DsK BR(Ds K)/BR(Ds ) = 1/15 while (Ds K)/(Ds ) = 70 thanks to the RICH PID Fermilab 3th May 2003

17. gfromBs D-s K+ , D+s K- Needed: • Hadronic trigger • K/p separation • Good proper time resolution From the measurement of 4 time-dependent asymmetries one gets g-2dg (with 2dg from BsJ/yf) 2 same order tree level amplitudes (3) : large asymmetries, NP contributes unlikely Sensitivity depends upon • relative amplitudes • strong phase difference • values of g, Dms , DGs /Gs For Dms=20 ps–1: s(g) ~ 10o For Dms=30 ps–1: s(g) ~ 12o In one year: 8k BsDsKreconstructed events Same principle holds for B0D*p, (study at the time of TP gives similar precision on g, a new evaluation is under way) Fermilab 3th May 2003

18. dgfromBs J/y f In SM fS = -2dg = -2l2h ~10-2 Sensitive to New Physics effects in the Bs-Bs system J/y f is not CP eigenstate: needs fit to angular distributions of decay final states as a function of proper time In one year: 109 k events Bs J/y (m+m-) f 19 k events Bs J/y (e+e-) f Assuming Dms=20 ps–1: s (2dg) ~ 2o s=36±1 fs will be updated for TDR Determination of DGs s( DGs/ Gs) ~ 0.03 for DGs/Gs = 0.15 Fermilab 3th May 2003

19. bfromB0 J/y Ks The ‘gold plated’ channel at B-factories Precision measurement of this parameter is very important: =sin 2b =0 in SM LHCb will bring a lot of statistics to this channel, which can be used to look into higher order effects, and fit Adir will be updated for TDR In one year with 119k events: s (sin 2b ) ~ 0.02 Comparing with other channels may indicate NP in penguin diagrams Fermilab 3th May 2003

20. Rare decays:B0 K0*g BR( B0 K0*g ) = (4.30.4)10-5 Direct CP violation in SM <2%  Sensitive to New Physics effects g W b u,c,t s Mass resolution ~72 MeV Background from B0K*p0 can be rejected using K* helicity In one year: 20k events B0 K0* (K+p-) g triggered and reconstructed Fermilab 3th May 2003

21. Bc mesons • LHCb acceptance ~30% • Possible CPV with Bc J/yD, Bc  DsD, DD, ... • Precision measurement of mass, life-time CDF: mBc= 6.4  0.4 GeV, tBc ~ 0.5 ps p (GeV) LHCb preliminary study s(ppBc) ~300 nb 109 Bc/ year Bc  J/y p (BR ~10-2) e ~ 2% 12k events/year Background from B J/y X and prompt J/y reduced cutting on the distance between primary vertex and Bc vertex M( J/y(mm) p) GeV/c2 Fermilab 3th May 2003

22. Current status of LHCbPhysics Reach in 1 year (2fb–1) *Precisions obtained by scaling old results with the new yields All numbers will be updated together with more channels in the re-optimization TDR (September 2003) Fermilab 3th May 2003

23. Systematics in CPV measurements Possible sources of systematic uncertainty: • Asymmetry of b vs b production • Detector efficiencies which depend on charge can bias tagging efficiencies can fake CP asymmetries • CP asymmetry also in background processes • Alternate runs, swapping the orientation of magnetic field • Use control samples available with high statistics: Bs Dsp 72k events/year B0 J/y K* 600k events/year B J/y K 600k events/year • Study CP asymmetries in the B mass side bands (from Technical Proposal) Fermilab 3th May 2003

24. Conclusion • LHCb is a dedicated detector for B physics measurements in many channels from the beginning of LHC • A very precise determination of CKM unitarity triangle will be possible • Detector performances are being evaluated with a realistic and complete Monte Carlo simulation • LHCb offers an excellent opportunity to spot New Physics signals beyond Standard Model very soon at LHC Fermilab 3th May 2003

25. back-up slides Fermilab 3th May 2003

26. p0 reconstruction • PreShower (scintillator+Pb+scintillator) 2X0 • ECAL (Pb+ “shashlik” scintillator) 25X0 s(E)/E=10% /E1.5% • HCAL (Fe+scintillator) 5.6 lI s(E)/E=80% /E10% pT>200 MeV Purity ~20% in range 0.1<m <0.17 GeV/c2 Fermilab 3th May 2003