The LHCb Perspective

The LHCb Perspective Jim Libby – University of Oxford UK SuperB Factory Workshop

Outline • Physics goals of SuperB and LHCb (almost) identical • Indirect search for New Physics in heavy flavour decay • In particular CP violating and rare B decays • Is there a synergy with a Super B factory? • Synergy to symbiosis • LHCb detector and status • LHCb core programme • Comparison to SuperB • An upgraded LHCb • Conclusions UK SuperB Factory Workshop

Symbiosis-living together • In symbiosis, at least one member of the pair benefits from the relationship • The other member may be: • injured • relatively unaffected • may also benefit ( = mutualism) UK SuperB Factory Workshop

UK SuperB Factory Workshop

Requirements for flavour physics at the LHC • Triggering: • 6 in 1000 inelastic pp collisions at 14 TeV contain a bb pair • Average of 1 interaction/bunch crossing (40 MHz) • Reduce event rate for mass storage at 2 kHz • Also require standard B physics tools • Vertexing • Particle identification • Good invariant mass resolution • Neutral reconstruction • Flavour tagging • A large number of bb events! UK SuperB Factory Workshop

Acceptance and luminosity • In the forward region at LHC the bb production cross section is large • All types of B hadron • LHCb uses the forward direction • 4.9 > h>1.9 • Both hadrons containing the b & b quarks are likely to be within the acceptance • B hadrons are moving with considerable momentum ~100 GeV/c • Design luminosity L=2×1032 cm-2s-1 • Maximises number of single interactions • 1012B hadrons in 107 sec = 1 LHC year Pythia production cross section pt 100 mb 230 mb h UK SuperB Factory Workshop

LHCb detector Muon Detector Tracking stations proton beam interaction region Trigger Tracking UK SuperB Factory Workshop

LHCb cavern snapshot RICH 1 - photo-detector magnetic shielding Muon shielding and electronics tower HCAL and ECAL modules Magnet – mapped RICH 2 WILL BE READY FOR 2007 PILOT RUN UK SuperB Factory Workshop

LHCb trigger • First level hardware trigger • High pthadrons, leptons and photons • Veto multiple interactions • If event passes 1st level all sub-detector data readout at 1 MHz to Higher Level Trigger farm • Adaptable software trigger • Fast VELO tracking to identify high impact parameter tracks • Match to high ptobjects that fired first level • 2 kHz output rate • Inclusive D* (300 Hz) – PID calibration and charm physics • Dimuon (600 Hz) – B→J/ψX with no impact parameter selection • Inclusive b→μ (900 Hz) – data mining and calibrations • Exclusive B decay (200 Hz) – physics channels UK SuperB Factory Workshop

Tracking and vertexing BsDs All performance results with PYTHIA+GEANT4 simulation unless otherwise stated • Proper time resolution ~ 40 fs • BsDsh (h=π,K) • Bs J/  • Essential for time dependent Bs measurements BsDs UK SuperB Factory Workshop

Kaon ID: ~88% Pion mis-ID: 3% B→h+h- Particle ID No RICH • Low momentum – Kaon flavour tag(b→c→s) • High momentum – Background rejection for exclusive B decay reconstruction ππhypothesis UK SuperB Factory Workshop

l- K– Qvtx D B0 Bs SV PV K+ Flavour tagging • Most powerful tag is opposite kaon (from bcs) • Combined D2 ~ 6.9% (Bs) or 4.8% (B0) • Recent multivariate approach ~9% for Bs Cut UK SuperB Factory Workshop

LHCb Physics Programme Sampler • Bs mixing phase and lifetime difference • BsJ/ • Several routes toγ • Bs→ DsK – tree only • Bd→π+π-andBs→ K+K- – tree and penguin • B-→D0K- and B0→D0K*(892)0 – tree and D0 mixing • αwithBd→ρπ • Rare decays • Bs(d)μ+μ- • BdK *(892)0μ+μ- • Bd K *(892)0γandBs γ UK SuperB Factory Workshop

fs and DGs from BsJ/ • Bs analogue of Bd→J/ψKs measures the Bs mixing phase • fs = –arg(Vts2) = –22 ~ –0.04 in SM • Large CP asymmetry would signal Physics Beyond SM • J/ is not a pure CP eigenstate • Admixture of 2 CP even and 1 CP odd amplitudes • Need to fit angular distributions of decay final states as function of proper time • Requires external msfrom Bs→Dsπ • Exploits excellent proper time resolution • 1 year predictions with ms= 20 ps-1 • 125k events with B/S~0.5 • (sin s)~0.031 • (s /s)~ 0.011 • 3σ SM sensitivity to sin safter 5 years • Also add pure CP states BsJ/η(‘) UK SuperB Factory Workshop

BsDsK BsDs gfrom Bs DsK • 2 amplitudes (b→c and b→u) of same magnitude (~λ3) interfere via Bsmixing • insensitive to new physics • large interference effects expected • 2 time dependent asymmetries • Bs (Bs)  D-sK+andBs (Bs)  D+sK- • 5400 signal events/year with B/S<1 • PID and mass resolution reduce contamination from Bs Dsπ ~ 10% UK SuperB Factory Workshop

DsK asymmetries (5 years, ms=20 ps–1) Ds–K+ Ds+K– g from Bs DsK • Fit 2 time-dependent asymmetries • phase of D-sK+= D + (g + fs) • phase of D+sK-= D- (g + fs) • sfrom Bs → J/ψ to extract Δ and γ • 1 year sensitivity: • Assuming Δms= 20 ps-1 and -20°<Δ<20° • s(g) ~ 14° • Statistically limited • 8-fold ambiguities in g can be resolved • If DGs large enough, or • B0→Dp and U-spin symmetry UK SuperB Factory Workshop

B   (95% CL) p/K p/K Bd/s d Bd/s p/K p/K Bs KK(95% CL) g()  from B and BsKK R.Fleischer, Phys.Lett. B459, 306 (1999) • Large penguin contributions in both decays • Sensitive to New Physics • Measure time-dependent CP asymmetry for B and Bs KK • ACP(t) = Adir cos(Dmt) + Amixsin(Dmt) • Adir and Amix depend on g, mixing phases, and ratio of penguin-to-tree amplitudes (d eiq) • Exploit “U-spin” symmetry (ds) • dpp = dKK and qpp = qKK • Mixing phases from golden modes • 4 measurements and 3 unknowns, 1 year yields and sensitivity: • 26k B and 37k BsKK, • s(g) ~ 5° UK SuperB Factory Workshop

A1 = A(B0 D0K*0): bc transition, phase 0 A2 = A(B0 D0K*0): bu transition, phase + A3 = 2 A(B0 DCPK*0) = A1+A2, because DCP=(D0+D0)/2 gfrom B0 D0K*0 • Dunietz variant of Gronau, London and Wyler method • Exploits interference between two colour-suppressed diagrams • Measure 6 decay rates: B0D0(Kp,pK,KK)K*0 + CP conjugates • Allows g and other parameters to be extracted without flavour tagging or proper time determination • 80 precision on γwith one year’s data = strong phase UK SuperB Factory Workshop

B →DK Similar to B0-two interfering tree processes Now one diagram colour suppressed Look for decays common to Do and Do to access interference effects, which depend on 3 parameters: •  – b→u , b→c interference • rB – the ratio in magnitude of two diagrams (0.1 – 0.2) • δB – a CP conserving strong phase difference Two types of D0decay understudy: • Cabbibo favoured self-conjugate decays e.g. Ks, KsKK, KKππ • PreliminaryKsstudies6k events/yearwith B/S ~O(1) • Cabbibo favoured/doubly Cabbibo suppressed modes e.g. K, K • One year γsensitivity 50 UK SuperB Factory Workshop

m2(0–) +– 00 –+ m2(0+) Combined discriminant variable Angle from Bd 0–+ decays • Dalitz plot analysis (Quinn Snyder method) • Bd0–+ selection based on multivariate analysis • Use resolved and merged 0 • Expect 14k events per year, B(bb)/S < 1 • Toy MC study: • 11-parameter likelihood fits performed in time-dependent Dalitz space • B/S = 0.8 (flat and resonant bkg) gen=106° 1 year () ~10° UK SuperB Factory Workshop

AFB(s) for B0K*0 s = (m)2 [GeV2] Rare decays with leptons Bs→μ+μ- • BR ~ 3.5  10–9 in SM, can be strongly enhanced in SUSY • LHCb has prospect for significant measurement • ~30 events/year • Full simulation: 10M incl. bb events + 10M b, b events (all rejected) B→K*0μ+μ- • AFB very sensitive to new physics • Expect 4.4k events in 1 year • B/S < 2.5 • In 5 years 13% sensitivity to s(AFB=0) UK SuperB Factory Workshop

B0→ K0* g and Bs →f g sm~ 64 MeV/c2 B→ Kp g • B→K0* gexpected direct CP violation Acp<0.01 • 35k/year B/S>0.7 • B→fgTDCPV zero in SM • Sensitive to same new physics as TDCPV B0→ K*0(K0sπ)g • Selection optimises proper time resolution • 9.4k/year B/S>2.5 • Sensitivity studies in progress mKπ[GeV] st~ 60 fs Bs→ KK g UK SuperB Factory Workshop

…and much, much more • Other CP measurements, for example • sin 2β • sin (2β+γ) with B→D*π • α with B→ρ0 ρ0 • s withBs   (gluonic penguin) • Other rare decays e.g Bs  μμ • Other areas to be explored • B baryons • Bc physics – 14k/year in Bc→ J/ψπ • Charm physics (300 Hz of D*+→D0(h+h-)π+) • Control samples for control of systematic uncertainties UK SuperB Factory Workshop

Comparison to Super B SuperB (50 ab-1) LHCb (2 fb-1) • This was shown by N. Katayama at FCPC a couple of weeks ago • At first glance I’m working on the wrong experiment! • But: • LHCb ~2010 • SuperB ~2020 • Some missing LHCb info UK SuperB Factory Workshop

Comparison to Super B Bs • Added some information on several modes • Scaled LHCb to 10 fb-1 luminosity (2015) and reordered the measurements • Symbiosis! Common No IP Inclusive/ν UK SuperB Factory Workshop

Bop+p- BSfg BSJ/yf BSDSK- Possible LHCb upgrades • Simulation studies indicate we can run at 5×10-32cm-2s-1 and gain in statistics • Particularly dimuons • Vertex detector will be replaced because of radiation damage • Very radiation hard technologies would allow detectors to be closer to the beam • Pixels could be used in 1st level of the trigger to improve selection of hadronic modes • ECAL inner region replaced by PbWO4 to improve neutral performance UK SuperB Factory Workshop

Conclusions • LHCb will be ready for data taking next year • A large number of measurements will be made during the lifetime of the experiment • Largely complimentary to Super B programme • Performance might be enhanced with upgrades to vertexing, triggering and electromagnetic calorimetry UK SuperB Factory Workshop

“gold-plated” decay channel at B-factories for measuring the Bd- Bd mixing phase • needed for extracting γfrom B  ππand Bs  K K, or from B  D*π • in SM ~0, non-vanishing value O(0.01) could be a signal of Physics Beyond SM sin(2) from B0J/ KS ACP(t) (background subtracted) One of the first CP measurements at LHC: • demonstrate CP analysis performance • study tagging systematics Expected sensitivity: • LHCb: 240k signal events/year  stat(sin(2)) ~ 0.02 (1year, 2fb-1) (s(b)~0.6°) Search for direct CP violating term… LHCb UK SuperB Factory Workshop

B- →D0(K+p-)K- Atwood, Dunietz and Soni B-→D0K- (colour favoured) then : B-→D0K- (colour suppressed) then : • Both D0 and D0 → K+p- : Doubly Cabbibo suppressed Cabbibo favoured • For these decays the reversed suppression of the D decays relative to the B decays results in much more equal amplitudes → big interference effects • Counting experiment • Interference depends on 5 parameters: • From the B decays γ, rB andδB • rDK – the ratio in magnitude of two D decay processes • Well measured (PDG value 0.060) • δDK – a CP conserving strong phase difference UK SuperB Factory Workshop

Have 4 B± →D(Kp)K± rates we can measure: Two rates are favoured (1) and (3) Two rates are suppressed (2) and (4) – butsuppressed rates have O(1) interference effects as rB ~ rD Taking the relative rates have more unknowns than equations – need information from other decays eg. D → Kppp or the CP eigenstates KK, pp (rDKK=1, δDKK=0) (1) (2) (3) (4) B- →D0(K+p-)K- UK SuperB Factory Workshop

ADS 1 year sensitivity studies 1000 toy experiments-no background • Event yields • 60,000 favoured • 2,000 suppressed • B/S = 0.5 for both • Fit robust over range of strong D decay strong phases UK SuperB Factory Workshop

The LHCb Perspective

The LHCb Perspective

Presentation Transcript

LHCb

The LHCb trigger

The LHCb Experiment

LHCb

The LHCb experiment

LHCb

LHCb

The LHCb Upgrade

LHCb

LHCB

The LHCb Trigger

LHCb

The LHCb Experiment

The LHCb Upgrade

The LHCb Upgrade

The LHCb experiment

The LHCb Experiment

The LHCb Trigger