Search for New Physics in tt Final State in Boosted Regime at CMS

1. Search for New Physics in tt Final State in Boosted Regimeat CMS • Motivation • Analysis method • Jet topologies • Background estimation • Results • Summary Sam Meehan on behalf of the Group E Collaboration Example Boosted Top Event Display from CMS Group E - tt Resonances Search

2. Motivation • What are they searching for and why? • CERN has a top factory in the LHC • New physics will likely couple to the top (oddly heavy) • Benchmark models : RS-KK gluons , Z’ resonances • How are they doing this? • Using 5 fb-1 of 7 TeVpp data collected by CMS during 2011 • Reconstruct fully hadronic final state  gain in BR for top decay • Examine tt invariant mass spectrum for excess in data p t Z’, KK-gluon, Spaghetti monster … ???? p t Group E - tt Resonances Search

3. Analysis Overview • Massive resonances (>1 TeV)  boosted tops • ΔR ~ 2M/pT  R = 0.8 jets contain boosted top with few 100 GeV of pT • Derive data-driven estimate of dominant QCD background • Examine invariant mass of tt system for excesses • Set CLs limits on σ✕BR 1+2 – Trijet Channel : Type I top-tag jet + Type II top-tag from W-tag plus jet 1+1 – Dijet Channel : Require both jets to be type I top-tagged jets b W W (W-tagged) b Type-1 top candidate Type-2 top candidate Group E - tt Resonances Search

4. Top-tagging • Decompose C/A jet building algorithm from the final recombination to find subjets and then ask about their kinematics C/A Jets : R=0.8 dij = ΔR(i,j)/R diBeam= 1 Group E - tt Resonances Search

5. Top-tagging • Decompose C/A jet building algorithm from the final recombination to find subjets and then ask about their kinematics C/A Jets : R=0.8 dij = ΔR(i,j)/R diBeam= 1 Group E - tt Resonances Search

6. Top-tagging • Decompose C/A jet building algorithm from the final recombination to find subjets and then ask about their kinematics C/A Jets : R=0.8 dij = ΔR(i,j)/R diBeam= 1 This is just out working hypothesis to get a picture of how a boosted top may be formed t Group E - tt Resonances Search

7. Top-tagging • Decompose C/A jet building algorithm from the final recombination to find subjets and then ask about their kinematics C/A Jets : R=0.8 dij = ΔR(i,j)/R diBeam= 1 SubjetDecomposition : CheckpTi/pTjet > δP=0.05 and separation splitting Both pass Consider both as “subjets” Try to split both One Pass Softer protojet from radiation Discard softer Both Fail Irreducible Final subjet identified t Fails Passes t Group E - tt Resonances Search

8. Top-tagging • Decompose C/A jet building algorithm from the final recombination to find subjets and then ask about their kinematics C/A Jets : R=0.8 dij = ΔR(i,j)/R diBeam= 1 SubjetDecomposition : CheckpTi/pTjet > δP=0.05 and separation splitting Both pass Consider both as “subjets” Try to split both One Pass Softer protojet from radiation Discard softer Both Fail Irreducible Final subjet identified Both pass  subjets W b t t Group E - tt Resonances Search

9. Top-tagging • Decompose C/A jet building algorithm from the final recombination to find subjets and then ask about their kinematics C/A Jets : R=0.8 dij = ΔR(i,j)/R diBeam= 1 Both fail irreducible SubjetDecomposition : CheckpTi/pTjet > δP=0.05 and separation splitting Both pass Consider both as “subjets” Try to split both One Pass Softer protojet from radiation Discard softer Both Fail Irreducible Final subjet identified W b t t Group E - tt Resonances Search

10. Top-tagging • Decompose C/A jet building algorithm from the final recombination to find subjets and then ask about their kinematics C/A Jets : R=0.8 dij = ΔR(i,j)/R diBeam= 1 SubjetDecomposition : CheckpTi/pTjet > δP=0.05 and separation splitting Both pass  subjets Both pass Consider both as “subjets” Try to split both One Pass Softer protojet from radiation Discard softer Both Fail Irreducible Final subjet identified q’ q W b t t Group E - tt Resonances Search

11. Top-tagging • Decompose C/A jet building algorithm from the final recombination to find subjets and then ask about their kinematics C/A Jets : R=0.8 dij = ΔR(i,j)/R diBeam= 1 Both fail  irreducible SubjetDecomposition : CheckpTi/pTjet > δP=0.05 and separation splitting Both pass Consider both as “subjets” Try to split both One Pass Softer protojet from radiation Discard softer Both Fail Irreducible Final subjet identified q’ q W b t Kinematic Top-Tagging: M(subjets) ε [100 GeV, 250 GeV] min[M(i,j)] > 50 GeV t If subjets satisfy  Yay! Top-Tag! Group E - tt Resonances Search

12. W-tagging • Prune jets to increase mass resolution and tag them using mass drop technique Pruning Mass Drop W Tagging • Goal : better define M(jet) by removing “bad” constituents • Discard soft and large angle radiation by checking if • Z = min(pT1,pT2)/pT(1+2) < Zcut • D = ΔR12 > Dcut • Decompose into subjets • For 2 subjet jets, require: • mj-heavy/Mjet-total < 0.4 (mass drop μ) • 60 GeV < Mjet< 100 GeV W- tag ! C/A R=0.8 Jet Subjet 2 Subjet 1 μ>0.4 μ < 0.4 Mass Drop Group E - tt Resonances Search

13. Background Estimation (I) • Main Backgrounds • Standard Model tt taken from MC • Non-Top MultiJet (NTMJ)  data-driven technique using control region and estimated mistag rate for normalization • Mistag Probability • Using 1+2 topology  invert mass drop requirement on type 2 top μ>0.4 to obtain QCD fake sample with “same” kinematics • As function of type 1 top pT calculate top-tag mistag rate 50-60% efficiency plateau Pm(pT) = Probability of mistagging at jet pT 4-5% mistag probability plateau Group E - tt Resonances Search

14. Background Estimation (II) • Dominant NTMJ background taken from loosened selection in each channel • Event-by-event weight calculated as mistag probability for pT of probe jet • Background shape extraction • Probe jet mass distribution kinematically biased • Replace mprobe-jet in probe-jet four vector by random value drawn from NTMJ MC in [140,250] GeV • Closure of procedure tested on MC 1+2 – Trijet Channel : Tag type 2 candidate using two jets in single event hemisphere Third jet is “probe jet” 1+1 – Dijet Channel : Tag type I candidate Second jet is “probe jet” Group E - tt Resonances Search

15. Results 1+2 Channel 1+1 Channel • Combined SM tt(red) and MultiJet(yellow) backgrounds compared to data • Dominant systematics shown in grayed bands: • Trigger, JES, Luminosity, reconstruction efficiency • No significant excess observed Group E - tt Resonances Search

16. Interpretation of Results • Resonance search: • Limits set on σ✕BR as a function of resonance mass using CLs method with likelihood ratio as test statistic • tt Continuum Enhancement • Limits set on σ(tt) enhancement rom new physics using CLs method SM + New physics SM only Excluded M(Z’)>1.6 TeV Group E - tt Resonances Search

17. Conclusions • First search constraining mtt > 1 TeV and using developing jet substructure techniques • No indication of new physics (Z’, KKG, ???) coupling to top pairs • Limits on σ✕BR set for benchmark models and general broad excesses • Substructure is interesting and will allow us to probe high pT regime in hadronic final states • Many thanks to all organizers of ESHEP, and especially Maurizio for many wonderful discussion sessions these past two weeks!!! Group E - tt Resonances Search

18. Group E Collaboration • Boris Bulanek • Alexander Gramolin • Claudio Heller • Brett Jackson • HouryKeoshkerian • Olga Kochebina • Lukas Marti • Sam Meehan • Nicola Orlando • Maurizio Pierini • Leonid Serkin • Rosa Simoniello • Jared Sturdy • Dmitry Tsirkov • Xiaoxiao Wang • ChristophWasicki • Adam Webber • Jonas Weichert Group E - tt Resonances Search

19. Backup Group E - tt Resonances Search

20. Systematics • Determination of efficiency: Trigger, jet energy scale • Mistag probability: statistics (high-mass region), systematic associated to mass spectrum correction (low-mass) • Shape of the tt_bar invariant mass: Renormalisation and factorisation scales. Group E - tt Resonances Search

21. Topcolor: width = 10% Group E - tt Resonances Search

22. Randall–SundrumKaluza–Klein gluon production Group E - tt Resonances Search

23. CMS Detector Group E - tt Resonances Search