Study of VBF H-> tt ->lep+had

1. Study of VBF H->tt->lep+had Junichi Tanaka ICEPP, Univ. of TOKYO Discovery of Higgs and Supersymmetry to Pioneer Particle Physics in the 21th Century

2. Outline • Introduction • Study of 3rd jet by ME event generator • Study of fake BGs • Summary • Prospects : Discovery Potential of SM Higgs

3. VBF SM Higgs Production & Decay @ LHC Excluded by LEP Production Decay t+t- LEPEWWG2005S 114.4 < mH < 219 GeV/c2 @95% C.L. • VBF H->tt at low-mass region (mH = ~120GeV) • Large production cross section and branching ratio: sxBR ~ 300fb

4. Vector Boson Fusion Process • Characteristics • High Pt jets in forward region • Rapidity gapRight fig : h*3 = h of 3rd jet – average of h of 2 forward jets • Signal … a dip in the center • BG … a peak in the center -> jet activities depend on structure of color flow. Rapidity gap f h PRD59(1999)14037 hep-ph/9908378 (EW) Treatment of 3rd jet is important in this mode!

5. Study @ ATLAS ATLAS Scientific note: Eur.Phys.J.C32S2:19-54,2004 BG by Comphep • VBF H->tt is one of promising channels near the LEP limit. (left fig) • Reconstruct M(tt) by using missing Et and observe a peak (right fig) on the right side of the Z mass peak. “VBF H->tt” is one of discovery channels at the low mass region. VBF H->tt

6. Motivation • Improvement and progress of our tools since the previous studies (Eur.Phys.J.C32S2,19,2004, the pervious slide) 1) Events with multi jets can be generated by the recent ME event generators. • 3rd jet was evaluated by Parton Shower (PS) model in the previous studies. • We evaluate 3rd jet by the ME event generator. 2) Environment of reconstruction and full simulation, which will be used in 2007, is available. • Fake rate can be estimated from the full simulation, which is based on Geant4. • Large QCD backgrounds, which have not been considered in the previous studies, are checked by using results of the full simulation.

7. Type of Simulation • Full simulation • Based on Geant4 • Initial layout • Used for detail studies • Development of reconstruction tools, for example, tracking, reconstruction of missing Et, Particle ID tools (e, m, tau, b, g). • Fake rates, crack effect for missing Et and so on • Take much time, typically, ~15mins/event with 3GHz CPU. • Fast simulation • Based on parameterized performance of full simulation results • Used for the BG study, where we need high statistics. • Most of today’s results are obtained by the fast simulation.

8. Study of 3rd jet by ME event generator

9. ME ALPGEN + PS • Alpgen (M.L.Mangano) is one of the ME event generators. • Studies using ME event generators becomes popular. • ME has an advantage for producing high Pt jets. • To remove collinear and soft divergence, Pt and Rjj are required at parton level. • Soft and collinear kinematical regions are covered by PS. • We produced exclusive samples for Z+njets(n=2,3,4) with modified ALPGEN ver1 (small weight events can be produced). • “Z+njets” is a dominant BG. • MLM method is used to avoid double counting. The similar method is officially introduced from ver2.

10. To Avoid Double Counting • We use the following method (“our MLM method”) to avoid the double counting of events: (not CKKW method) Veto events having jets (Pt>20GeV) at the outside of cone (dR=0.4), whose center is defined by the direction of a ME-parton. ME-parton Rec-jet Bad Good See T.Sasaki’s talk later

11. Pt and h Distributions Alpgen sample(ver1), after lepton cut, normalized to 1fb-1. • 3rd jets with high Pt increase. • 3rd jets become more central. It has a large effect on Central Jet Veto. • Pt and h of 3rd jet depend on the number of jets. Cannot ignore them. Pt of 3rd jet eta of 3rd jet preliminary “Z2j” “Z2j”+”Z3j” “Z2j”+”Z3j”+”Z4j” with MLM method to avoid double counting preliminary log10Pt 25GeV 100GeV

12. No additional jet in the rapidity gap CJV Survival Probability • Central Jet Veto (CJV) : Veto events having additional jets with a “given” Pt in the rapidity gap. • Survival probability of “Z+2j” is higher than “Z+3j” and “Z+4j” due to smaller jet activity in the rapidity gap. • ~40% of Z+njets (n=2,3,4) remains in total in case of Pt=20GeV. preliminary jet t t jet f Rapidity gap h (additional jets in the rapidity gap)

13. M(tt) Distribution After all the selection criteria • A amount of remaining Z+2j is large due to large cross section and high CJV survival probability. • Z+3j and Z+4j still remains. They are not negligible. • Since resolution becomes worse as the number of jets increases, their tails can contribute to BGs. L=30fb-1 Z+2j Z+3j Z+4j preliminary Signal region

14. Study of fake BGs

15. Origin of Fake Lepton • Since cross section (x-sec) of events with QCD jets is much larger than that of the signal (x-sec~300fb), we suffer from these events, which have fake leptons from jets.W j j j -> W t j j : x-sec ~ >10nbj j j j -> e/mt j j : x-sec ~ >10mb • Fake Tau • 1 or 3 p+- with p0, which have most of energy of a jet • Fake Electron • Pair production of gamma (from p0) • Dalitz decay • p+- and p0 with E/p~1 • B/D semileptonic decay • Fake Muon • pion punch through • pion decay in flight • B/D semileptonic decay

16. Tau Reconstruction and ID • Hadronic decay: 1prong ~50% and 3prongs ~15% • We need to identify tau-jets from many QCD-jets. Charged tracks : 1 or 3 Photons from p0 • Reconstruction : two ways at ATLAS 1) Cell based : start from cells, which is the similar as cone jet algo. 2) Track based : start from charged track(s) • Properties of tau-jet : for identification • 1 or 3 charged pion tracks • Narrowness and Isolation

17. Tau Rec/ID Performance Cell based method “Fake rate of 10-2” means we misidentify one QCD jet as a tau in 100 QCD jets. Depend on Pt and type of jet. Gluon fake rate is better than quark fake rate dueto difference in narrowness. Light Quark Gluon fake rate preliminary 20<Pt<40GeV 40<Pt<60GeV 60<Pt<100GeV 100<Pt<140GeV efficiency This result is parameterized and then is used in fast simulation. At least we need ~50% eff. with these fake rates for the discovery with L=10fb-1.

18. e/m Fake Rates • Fake rates of electron and muon from jets are obtained from QCD di-jet samples using the full simulation. • See O.Jinnouchi’s talk later. • Typical performance Jet -> e : ~10-3 Jet -> m : ~10-4 • These results are taken into account in the fast simulation to evaluate BG contributions.

19. W+3jets & 4jets Corresponds to L ~ 70fb-1 W j j j -> W t j j j j j j -> e t j j • W+3j and 4jets remain with the same order of Z+njets. • Improvement of tauID for both cases and decrease of fake electron for 4jets are critical to decrease these BGs. Corresponds to L ~ 10fb-1 4jets W+3jets preliminary fake(e->jet) : 10-3 preliminary (Signal region:110-135GeV)

20. Signal (m=120) very preliminary Z+nj(QCD) M(tt) and Significance L=30fb-1 Z/ttjj(EW) tt, WWjj • We assume that lepton(e,m) efficiency is 85%. • Significance becomes worse by a factor of 2 due to the new backgrounds. • We need to improve tauID/fake electron and to optimize cuts. +”jjjj” A a kind of BGs is the same as our paper(page5). B C +”W+3jets” 10 sBG=0.18fb sBG=0.43fb sBG=0.73fb 10 10 sSIG=0.45fb Signal region:110-135GeV

21. Summary • VBF H->tt->lep+had is important for the SM Higgs discovery in the low mass region (mH~120GeV). • We evaluated 3rd jet by the ME event generator. • There are differences in Pt and h of 3rd jet by the number of jets. • Central jet veto survival probability and tail of M(tt) depend on the number of jets. • We should use ME generators for multi-jets studies as much as possible. • We studied fake BGs. • W+3jets and 4jets become large BGs for the lep+had channel. • We need to improve our tauID and other PID performance. • We must understand QCD BGs for any LHC physics since their x-sec is very large in the LHC. (maybe beyond our expectation…)

22. Discovery potential of SM Higgs ATLAS-PHYS-2004-005 preliminary NB: not include our latest results. 10fb-1 ATLAS Today L=10fb-1: VBF tt(ll+lh) ~ 2.6 gg ~ 5.0 @ mH=120GeV 200 120GeV Two promising channels at mH=~120GeV! We are preparing for this discovery!

23. Backup

24. ATLAS (A Toroidal LHC ApparatuS) E,P resolution (P ~ 100GeV) : m ~ 2% e, g ~ 1.5% Jets ~ 8% • 40MHz beam crossing • Readout channel = 160M channels • Raw data = 320Mbyte/sec • (1TB/hour) • Inner tracking system : 2T solenoid magnet • Liq. Ar EM calorimeter • Muon spectrometer : air-core troidal magnet

25. Summary of SM Higgs Studies ATLAS

26. Hadronic tau decay mode Branching ratio of H->tt : • BR(lep-lep) = ~12% • BR(lep-had) = ~46% “Lep-had” mode plays an important role for the Higgs discovery. factor of ~4 Mtt Distributions of VBF H->tt ＭＨ=120GeV ATLAS (em only) ATLAS

27. Fake rates very preliminary in 10-4

28. Simulated data • W(->ln)+3jets • Alpgen ver1 • Jet condition : Pt>15GeV, |eta|<5, Rjj>0.7Max(J1,J2)>30GeV, M(J1,J2)>200GeV, deltaEta(J1,J2)>2 • x-sec = 1.4nb … very large! • 4jets • Alpgen ver1 • Jet condition : Rjj>0.7 • Forward region : Pt>30GeV, eta1xeta2<0, |eta1-eta2|>2.5Mjj>350GeV, |eta|<5.0 • Central region : Pt>20GeV, |eta|<2.7, Mjj>80GeV • x-sec = 2mb … very large!!!

29. qqH -> qqtt -> qq lep had tau->e FWJet1 FWJet2 tau->h (1prong+pi0) Missing Et We’ll look this type of event in the real data !!!

30. ME+PS • Z2j sample z2j without MLM method • Z3j sample z2j with MLM method + z3j without MLM method • Z4j sample z2j with MLM method + z3j with MLM method + z4j without MLM method