1 / 17

Tevatron Searches for Beyond-SM Higgs

Tevatron Searches for Beyond-SM Higgs. Alexei Safonov (Texas A&M University) For CDF & D0 Collaborations. Higgs. Standard Model Higgs: Higgs mechanism generates particles masses Single physical scalar H, coupling ~m f Higgs is unavoidable in most extensions of SM Supersymmetry:

elewa
Download Presentation

Tevatron Searches for Beyond-SM Higgs

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Tevatron Searches for Beyond-SM Higgs Alexei Safonov (Texas A&M University) For CDF & D0 Collaborations

  2. Higgs • Standard Model Higgs: • Higgs mechanism generates particles masses • Single physical scalar H, coupling ~mf • Higgs is unavoidable in most extensions of SM • Supersymmetry: • Radiative EWSB (mh<135 GeV) • Several Higgses: h, H, H+/-, A • Possible non-universality in coupling • Production enhancement likely • Little(st) Higgs: • Three-scale model • Light Higgs h • Also A,H,H+/-,H++/-- • … • Compared to the zoo of SUSY final states and complicated phenomenology, Higgs is an “easy” target for searches ~tanb A. Safonov (Texas A&M)

  3. Higgs Searches at the Tevatron • In this talk: • Neutral Higgs Searches • Multi-b final state (SUSY) • Di-tau final state • Charged Higgs • Analysis of top decay branching ratios • Doubly Charged Higgs (LR-sym. models) • Lepton Flavor Violation involving 3rd generation A. Safonov (Texas A&M)

  4. MSSM Higgs Production MSSM Higgs coupling to b, t ~tanβ gluon fusion Higgs decays: • bb(~90%) • tt(~5-13%) b-quark fusion A. Safonov (Texas A&M)

  5. MSSM Higgs+b(b)→bbb(b) • Look for associated production with b(b) (suppress multi-jet bg) • Require >=3 b-tagged jets (sec. vtx) • Form invariant mass of the two highest-ET jets – binned fit Data sample: ~260 pb-1 260 pb-1 • b-tag rate estimated from data • Acceptance ~0.3-1% (mA=90-150) • Major syst uncertainties: • b-tagging (15%) • JES/resolution (9%), • signal simulation (5%) • trigger (9%) • luminosity (6.5%) • Bg estimation (3%) 260 pb-1 A. Safonov (Texas A&M)

  6. MSSM Higgs+b(b)→bbb(b) • No evidence of signal • Interpretation of the results: mhmax and no-mixing scenarios with μ<0 • The search is sensitive down to tanβ~50-55 for m(A)~90-150 GeV 260 pb-1 260 pb-1 A. Safonov (Texas A&M)

  7. CDF • Reconstruction of th: • Cone algorithm • Energy from trks and p0’s • Isolation veto (trk, p0) • Hadronic system: • mhad< 1.8 GeV • Ntrk = 1,3 ; charge = ±1 Neutral MSSM Higgs→tt • Event selection • Leptonic tau (tℓ :t→ℓnn; ℓ=e,m) • Hadronic tau (th :t→hadrons n) • Opposite charge of tℓ ,th , bg supression cuts • Acceptance ~1-2% (mA=90-150 GeV) • Dominant bg: Z/g*→tt • Z/Higgs separation: mvis(ℓ,th,ET) Before Ntrk and opposite charge cuts A. Safonov (Texas A&M)

  8. CDF Neutral MSSM Higgs→tt • Observed 487 ev, expect 496± 5.4(stat) ± 27.7(sys) ± 24.8(lum) • Dominant systematic uncertainties: • Particle ID: th (3.5%), e (1.3%), m (4.6%) • Jet→t mis-ID estimate (20%)  3% on total bg • PDF’s (5.7%) • Luminosity measurement (6%) • Set limits by performing likelihood fit of mvis(ℓ,th,ET) distribution Example fit for mA=140 GeV A. Safonov (Texas A&M)

  9. CDF Neutral MSSM Higgs→tt • Interpret the results in mhmax and no-mixing scenarios with m<0 and m>0 • bb and tt Higgs decay channels are complementary • Projections are based on the current analyses techniques • A lot of improvements in the works A. Safonov (Texas A&M)

  10. Neutral MSSM Higgs→tt • Fresh off the press D0 result: • Include e+thad,m+thad, e+m • NN for tau ID: 3 types of had taus • Fit invariant mass distribution and set limit • Combine with the result in bbb(b) channel • No signal, set limit • Lots more data to come • Taus become really important A. Safonov (Texas A&M)

  11. CDF Charged MSSM Higgs • Production: • Major decay modes: • H+→t+n • H+→cs • H+→t*b→W+bb • H+→W+h→W+bb • BR’s depend on: • tan β, m(H+) • Differ from W+ BR’s t →bH+ (mH < mt-mb) A. Safonov (Texas A&M)

  12. CDF Charged MSSM Higgs • Check consistency of the final states with SM expectation • Interpret for several MSSM scenarios, tan β, and mH • Lint = 192 pb-1 • Look at four tt final states: • di-lepton + jets • lepton + jets (=1 b-tag) • lepton + jets (≥ 2 b-tags) • lepton + tau + jets A. Safonov (Texas A&M)

  13. CDF Charged MSSM Higgs Consistent with the SM No-mixing benchmark scenario mhmax benchmark scenario A. Safonov (Texas A&M)

  14. CDF Doubly Charged Higgs • Little Higgs and L/R symmetric models (incl. SUSY) • Elegant solution for massive neutrinos via see-saw mechanism • H++ can be light • vR ~ 1010 GeV, mH±± ~ 100 GeV • DY-like H++ pair production • Constrained by the r parameter • s(m = 100 GeV) = 120 fb (1000 times less than Ztt) • Published results in e/mu channels supersede LEP • Tau decays: start with e/mu+tau final states A. Safonov (Texas A&M)

  15. CDF Doubly Charged Higgs Zee removal not yet applied • Selection: • Electron pT>20 GeV • Tau pT>15 GeV • LTC w/ seed track pT>7 GeV • Two event categories: • 3p channel: e+tau+LTC • 4p channel: e+tau+LTC+LTC • Backgrounds: • Z/g*(ee)+jets (most difficult) • ZZ, WZ • QCD (easy to remove) • Others less significant HT>190 GeV Note the similarity with a tri-lepton search A. Safonov (Texas A&M)

  16. CDF Doubly Charged Higgs • Open the signal box: • No events found • Expected ~0.3 events • No discovery, but can set an exclusion limit • mH++>115 GeV – new CDF result Muon+Tau channel is nearly done. Box not opened, but similar sensitivity A. Safonov (Texas A&M)

  17. Summary and Outlook • The Higgs boson is being hunted at the Tevatron • Various scenarios and Higgs species • D0 and CDF are competing, will soon start combining results • Taus are in the game at both CDF and D0 • Very important for Higgs in SUSY • May well turn out to be very useful for SM Higgs • No smoking gun with the analyzed data, but already 2-5 times more data on tape • With some luck, you may hear from us before LHC A. Safonov (Texas A&M)

More Related