Searches for Neutral Higgs Bosons in Supersymmetric Extensions of the SM

1. Searches for Neutral HiggsBosons in SupersymmetricExtensionsofthe SM Markus Schumacher Klausurtagung Feldberg, 13. 12. 2008 • Standard Model (SM) • Minimal Supersymmetric • Extension ofthe SM (MSSM) • Next-to-Minimal Supersymmetric • Extension of the SM (NMSSM) • Motivation • StructureofHiggsSector • TheoreticalConstraints • Status of Searches • Prospects for Discovery

2. Theoretical constraints Particle masses and their “problem” • Experiment: all particles massive (except g + gluon) • Theory: forces described via gauge symmetries • Problem: SU(2)LxU(1)Y-Symmetrie: no masses for • - gauge bosons: W und Z • - fermiones: (l=Dublett, r=Singlett) „ad hoc“ mass terms destroy: • renormalizibility  no precision predictions e.g. mtop • good high energy behaviour: e.g. WLWL-Streuung violates unitarity at ECM ~ 1.2 TeV

3. The Brout-Englert-Hagen-Higgs-Kibble-Mechanismus The „Standard“-Solution: doublet of 4 skalar fields with appropiately choosen potential V = -m2 |f+f| + l |f+f|2 m2,l > 0 minimum not at f=0  spontaneous symmetry breaking Higgs field has two components: 1) omnipresent, homogeneous background field v= 247 GeV 2) Higgs-Boson H with unknown mass MH ~ Ölv H restaures unitarity if gHWW ~ MW gHff ~ Mf and MH not too large

4. Mass generation and Higgs boson couplings: F = v + H • interaction with v=247 GeV • interaction with Higgs-Boson H x x 2 v ggauge Higgs x 2 g gauge W/Z boson W/Z boson W/Z Bosonen MV~ gvgauge coupling Fermions mf~ gfv Yukawa coupling • VVH coupling ~ vev: only exists after electroweak symmetry breaking •  observation of VBF yields indirect hint to background field • only one free parameter: MH or l

5. Theoretical constraints on the Higgs boson mass • Unitarity in VV scattering: < 1 TeV • energy /temperature dependence of quartic coupling l Leftdiagram: increasingl requirel < 1 uptoenergyL  upperbound on MH=l(MH)v triviality/pertubativitybound Rightdiagram: decreasinglif mt large requirel >0 uptoenergyL  lowerbound on on MH=l(MH)v vacuumstabilitybound

6. Experimental constraints on MH • indirectprediction in SM: MW(Phys) = MW(Born) + t H W W W W W b 2 … mt + … ln(MH) MH < 154 (185) GeV (incl. dir. limit) • direct search at LEP: MH < 114.4 GeVexcluded at 95% CL • direct search at Tevatron: MH ~ 170 GeV excluded at 95% CL

7. Signal rates for SM Higgs boson production Preliminary Preliminary NLO (in QCD) (except ttH) HDECAY (Djouadi,Spira et al.) HIGLU, ... (SPIRA) • Vectorboson fusion qqqqH: 2nd dominant production • but additional signature from outgoing quarks • Hbb not selectable in ggH and VBF • H tt not selectable in gg->H •  VBF Htt promising channel close to LEP limit our group: H tt ll + 4 n (l=e, m)

8. Vektor boson fusion ppqqH with Htt  ll 4n • signal characteristics: - 2 forward jetswith rapidity gap - Higgs decay products in central detector ttll (l=e ,m): 40fb • background: reducible ---------------------------------- irreducible 833 pb NNLO:770(ll)+170(tt)pb 1.7pb (tt) MC@NLO ALPGEN/SHERPA SHERPA kinematics, colour flow, … mass reconstruction

9. VBF:Challenges and our plans • reconstruction of taggings jets Preliminary • central jet veto (pt>20 GeV, |h|<3.2) Preliminary EW QCD • mass reco. in collinear approximation sM/M~12to 14% dominatedbyEmiss 20% worseforlowlumi. pile-up • optimise algos and study influence of pile up and underlying event • - investigate minimum bias and Zmm+jets - use of tracking information

10. Mass distribution and background estimate • mass distribution after all cuts peak on shoulder of dominant Z BG  estimate from data needed tt H Zjj • Zjj shape from data jjZmmandjjZttmmidenticaltopology 1) select Z  mmevents 2) manipulatemstolooklike Z  tt  ll4n 3) applystandardselection • develop similar method for tt background • e.g. b-veto vs. b-tag, impact parameter cuts, …

11. Discovery potential • VBF H tau tau • all current ATLAS studies Preliminary Preliminary • optimise selection (especially for ll final state): • - supress reducible BGs (tt much larger than in previous study) • - multivariate techniques • - sophisticated statistical tools

12. Exclusion potential Preliminary Preliminary • for exclusion need signal efficiency and its systematic uncertainty • dominant influences by: • - jet energy scale  Z+jets • - parton shower + underlying event model  Z+jets, Minimum Bias • - central jet veto eff. from data  single top?, Z+jj?

13. Stability of the Higgs boson mass • the hierarchy problem: why is v=246 GeV <<Mplanckor MGUT • large corrections to Higgs mass without new symmetry: fine tuning to level 10-34 needed or cut off at 1 TeV • divergence cancelled by particle with: D spin = ½, ~ same mass, same coupling if mass correction ~ O(100 GeV)  MSUSY~O(1TeV)

14. Other arguments for SUSY • largest symmetry of a unitary, interacting field theory = • Lorentz invariance x gauge symmetry x supersymmetry • link to gravity: most string models are supersymmetric • local Supersymmetry incorporates gravity • Grand Unification (GUT) possible: • Cold Dark Matter (CDM): lightest SUSY particle (LSP) might be stable • Baryon asymmetry in universe (BAU): can maybe explained

15. Parameters in SUSY (with R-Parity) • Minimal SUSY: one spartner for each SM particle, no new parameters • only freedom in Superpotential • „the problem“: SUSY broken in nature: (e.g. no spin 0 partner of electron) • no „real“ model for SUSY breaking yet  parametrise 105 additional parameters to describe SUSY breaking in specific models: mSUGRA, GMSB, AMSB,… ~5 parameters

16. The MSSM Higgs Sector in the Nutshell • SUSY requires 2 Higgs doublets • – masses for up and down type fermions • - anomaly free •  5 Higgs bosons: 3 neutral + 2 charged • scalar potential w/o SUSY breaking „lH4" given by gauge couplings, no EW-symmetry breaking • scalar potenital after SUSY breaking • different m1, m2 evolution  m2 negative  triggers EW-symmetry breaking • after EWSB: two free parameters in Higgs sector (v1 + v2 = vSM) 2 2 2

17. The MSSM Higgs Sector in the Nutshell • at Born level: - 2 parameters: tanb=v2/v1 and MA - CP conserved  2 neutral CP-even h,H + 1 CP-odd A - upper mass bound (quartic coupling = gauge couplings): Mh < MZ • large loop corrections from SUSY breaking sectoresp. top/stop mh < 133 GeV(+-3GeV) for mtop=175 GeV, MSUSY=1TeV in constrained MSSM a la LEP/LHC corrections depend on 5 SUSY parameters: Xtmixing in stop sector M0common sfermion mass at EW scale M2, SU(2) gaugino mass at EW scale, M1 from GUT relation Mgluinogluino mass mHiggs mass mixing parameter 5 parametersfixed inthe benchmark scenariosconsidered • mSUGRA: Xt, M0for Higgs and sfermion, M1/2for gauginos, sign m, tanb

18. MSSM Higgs Bosons Phenomenologie • modified couplings gMSSM =xgSM • no coupling of A to W/Z • small a  small BR(htt,bb) • large b  large BR(h,H,Att,bb) a = mixing btw. CP-even neutral Higgs bosons • new production mode: b(b)Higgs • Higgs boson mass pattern

19. Constraints on theHiggssector • MSSM bounds Constrained MSSM: Mh<133 GeV for mtop=175 GeV, MSUSY=1TeV General MSSM: Mh<150GeV • EW precisiondata, dark matter density, am, bsgin CMSSM = mSUGRA precisionfrom DM, am, bsgconstraints

20. Constraints on theHiggssector: direct searches • LEP: investigated 5+3 benchmarks Mh/A<~ MZ excluded at 95% CL • TEVATRON: • largestsensitivityat large tan b • via bbH, Htt

21. „Old“ MSSM Scans based on LO TDR and VBF-SN results 4 CPC benchmark scenarios considered: Carena et al. , Eur.Phys.J.C26,601(2003) • MHMAX scenariomaximal mh < 133 GeV  conservative LEP exclusion • Nomixing scenariosmall mh < 116 GeV  difficult for LHC • Gluophobic scenario • small gh,gluonmh < 119 GeV • Small a scenario • small ghbb and ghtt mh <123 GeV theo. aim: harm discovery via gg h, hgg and hZZ4 l theo. aim: harm discovery via VBF, htt tth, hbb • mainly influence masses and couplings of h • phenomenology of heavy states very similar

22. Some technicalities 1) SM LO production cross sections (Spira) times MSSM correction factors (FH) Mt= 175 GeV 2) branching ratios from FeynHiggs (T. Hahn et al.) 3)efficiencies and background expectations from published „old“ MC studies 4) efficiency corrections for: (a) increased total width in MSSM w.r.t SM (b) mass degeneracy of h,H,A 5) evaluate signficance form signal and background rate counting experiment using Poissonian statistic no systematic uncertainties considered !

23. Corrections to Expected Signal Rates a) for part of MSSM parameter space: large Gtot  eMSSM = K eSM K = h b)signal overlap due to mass degeneracy of Higgs bosons count signal in mass window 1 = signal 1 + signal 2 in window 1

24. Vector Boson Fusion: 30 fb-1 (old LO, SN-Study) Preliminary h or H observable with 30 fb-1 • studied for MH>110GeV at low lumi running • same conclusion in other benchmark scenarios

25. Light Higgs Boson h: 30 fb-1 observable channels: VBFbbh hmm (tth hbb w/o syst. error) Preliminary Preliminary Preliminary difference mainly due to different mh in same (tanb,MA) point ( up to 17 GeV difference)

26. Small a scenario, h: 30 fb-1 • hole due to reduced branching ratio for H tt Preliminary Preliminary • covered by enhanced BR to gauge bosons • complementarity of search channels almost gurantees observation of h

27. Light Higgs Boson h: 300 fb-1 (VBF only 30 fb-1) Preliminary Preliminary • also hgg, hZZ4 leptons (tthbb) contribute • large area coveredby several channels  sure discovery and parameter determination possible • small area uncovered @ mh = 90 to 100 GeV • hgg sensitive in gluophobic scenario due to VBF, Wh, tth production

28. Heavy Neutral Higgs Bosons ATLAS preliminary • most promising: bbH/A, H/Att,mm s ~ (tanb)2 • old LO study: • tt lephad +  hadhad(M > 450 GeV) • new NLO study: tt leplep Preliminary Preliminary same BGs as VBF, Htt massreco. and BG estimate a la VBF no forwardjetand CJV but b-tag insteadof b-veto

29. Overall discovery potential in CP conserving MSSM 300 fb-1 Preliminary • at least one Higgs boson observable for whole parameters space in all CP conserving benchmarks • significant area where only lightest Higgs boson h is observable • discrimination via - observation in SUSY cascades or H SUSY decays? - investigation of properties of h? ATLAS preliminary similar results in other benchmark scenarios VBF channels , H/Attonly used with 30fb-1

30. SM or Extended Higgs Sector e.g. MSSM ? discrimination via VBF compare expected measurement of R in MSSM with SM prediction BR(h WW) BR(h tt) R = 300 fb-1 ATLAS prel. assumes Mh precisely known negelects syst. uncertainties D=|RMSSM-RSM|/sexp • similar study by M. Dührssen et al. incl. 13 channels and systematic uncertainties  VBF dominates

31. The CP violating complex MSSM • MSSM Higgs sector CP conserving at Born level • CP effects via complex couplings in loops At, Ab Mgluino • mass eigenstates H1, H2, H3 not equal CP eigenstates h,A,H „new“ Born level pars: tanb and MH+- • why complex SUSY breaking parameters? • - no a priori reason why they should be real • - complex parameters yield new source of CP violation needed • - electroweak baryogenesis (1st order) in complex MSSM still ok • if mstop<mtop and MH1<120 GeV

32. Phenomenology in the CPX scenario • H2,H3 H1H1, ZH1,WW, ZZdecays • H1,H2, H3 couple to W,Z H1 sum rule: Si gi (ZZHi) = gSM 2 2 H2 2 2 H3 • no absolute limit on mass of H1 from LEP • strong dependence of excluded region • on value for mtop • on calculation used FeynHiggs vs CPH

33. Discovery potential in CP violating MSSM CPX scenario(Carena et al., Phys.Lett B495 155(2000)) arg(At)=arg(Ab)=arg(Mgluino)=90o,,MSUSY = 500 GeV, At=Ab=Mgluino=1 TeV, m=2TeV, M2=200GeV 300 fb-1 300 fb-1 • yet uncovered region in parameter space for light Higgs boson (not yet studied) • promising channels: ttbbH+W-bbH1W+W-bbbblnqq Higgs in SUSY cascades,….

34. The m-problem • MSSM Superpotential • m: the only parameter with mass dimension bevor SUSY breaking • m not protectedbysymmetry, couldbe MGUT • but correct EWSB requires O(.1 to 1 TeV) • idea: replacembycondensateofnewscalarcomplexsingletfield S • whichis only coupledto MSSM Higgsfields • sevenHiggsbosons: 3 CP-even, 2-CP-odd, 2 charged • 5th neutralinofromsuperpartnerof S • severalvariants on themarket: NMSSM, MNMSSM,… • and also not SUSY singletextensions e.g. HEIDI …

35. Investigation of sensitivity in NMSSM • following variant considered: • six free parameters at Born level: • two benchmark scenarios (Iris Rottländer, M.S. in LH07 proc. hep-ph 0803.115) (more benchmarks in PhD thesis by I. Rottländer, CERN-THESIS-2008-064) • masses, couplings, BRs calculcated with NMHDECAY (Elwanger et al.) • same procedure as for „old“ MSSM scans (i.e. LO cross sections, TDR etc. efficiencies and background numbers)

36. Phenomenology in light A1 scenario • MH1 ~ 120 GeV and SM-like • H3,A2,H+- too heavy • MH2 ~ heavy and decoupled in unexcluded region • MA1 < MH1 /2 in almost whole plane • BR(A1 tt) • BR(H1A1A1)

37. Discovery potential in light A1 scenario • H1 discovery potential • H2 sensitvity Preliminary Preliminary H2 photons reach limited by BR(H1A1A1) ~ 55% contour H2 only in excluded region observable • other Higgs bosons too heavy or decoupled to be observable • need dedicated searches for HA1A1bbbb,bbtt,tttt or maybe sensitivity in SUSY decays

38. Plans for (N)MSSM Scans • create database for masses, couplings, BRs for various benchmark scenarios • provide consistent NLO cross sections - simple scaling not always thrustworthy (e.g. gluon fusion) - check approximations against dedicated programs • include mass shapes and systematic uncertainties a la SM • evaluate discovery poential and exclusion and significance plots for data • and possibility to discriminate SM and SUSY extensions • perform sensitivity studies for yet uncovered regions - need signal efficiency (and shape) in addition • look at new scenarios propsed by our theoretical friends • I do not believe in SUSY, other extensions to SM are also welcome

39. Final words • newstudiesconfirmgoodsensitivity for discoveryofHiggsbosons • in SM and CP conserving MSSM • CP Violating MSSM and NMSSM needfurtherstudiestoestablish • no lose situation • VBF withHttimportant • - for lowmassHiggsbosondiscovery • - discriminationbtw. SM andextendedsectors • - determinationofspin/CP andmaybemass • Higgssensitivitystarts at > 1fb-1 - due to limited signalrates (except H+-) - requiredgoodunderstandingofdetector • focus for firstdata: - improveandvalidatejetand ETMISS reconstruction (Z+jets) - investigateand tune underlyingevent model (min. biasandZ+jets) - understand backgrounds in phasespace relevant for Higgsbosonsearches

40. Back up

41. Discovery = significant deviationfrom SM expectation • significant:probability of background fluctuation <2.9x10-7equivalent to „5 sigmas“ for Gauss distribution • deviation:- new peak in mass distribution - excess in kinematic distribution • for discovery (event counting or more info): - only need knowledge of background - wrong modelling of signal (rate and shape)  non optimal search strategy  more data • for exclusion (and discovery potential) - need signal efficiency (and shape) in addition • determination of background: • (i) from data itself with little theory and MC input • via auxilary measurement from same data set • (ii) prediction from theory + MC + detector performance • background=lumi*cross section*acceptance*efficiency • signal-to-background ratio vs. background uncertainty crucial for discovery significance

42. Ist es ein Higgs-Boson? Jet 1 V Dfjj V Jet 2 Signal +Untergrund für 10 fb-1 Sensitivität für Ausschluss von CPE/CPO: HWW:~ 5 s mit 10 fb-1 Htt: ~ 2.5 s mit 30 fb-1 (MC-Generator VBFNLO von D. Zeppenfeld et al.) C. Ruwiedel Diplomarbeit BN 2006

43. Kein Higgs?  Anomale Eichbosonselbstkopllung Verletzt Unitarität bei Energien von ~ 1.2 TeV Restaurierung durch „Neue Physik“ • Untersuchung von ppjj WW jj ln ln Endzustand (VBF-Signatur) • sensitive Observable Azimuthwinkeldifferenz zw. den Leptonen M. Mertens Diplomarbeit BN 2006 Dfll Lept.1 Lept.2 vielversprechende Studie auf dem Weg MC-Generator WHIZARD (W. Kilian, J. Reuter, …)

44. Hmm: sensitivity Preliminary Preliminary Preliminary Preliminary

45. MSSM Cross section: Charged Higgs Bosons • light charged boson: production in top decay BR(tH+b) with Feynhiggs 2.6.2 • gbHt: calculated in NLO with program including dominant SUSY loop corrections via Db (taken from Feynhiggs) • decay branching ratios calcluated with Feynhiggs 2.6.2 results in mhmax scenario • production cross sections • decay branching ratios

46. Charged Higgs boson: search channels • light H+- (MH+- < Mtop) (PYTHIA) Preliminary MH+-= =130GeV tanb=20 • heavy H+- (MH+- >= Mtop) (MATCHIG) Preliminary • backgrounds: tt, single t, W+jets, QCD • top quark production dominant background in all topologies • systematic uncertainties: theo: 15% for tt cross section exp.: 15 to 40% for signal and background (E scale, b-tagging largest)  exctract background from control sample  ~ 10% background uncertainty

47. Charged Higgs boson sensitivity in mhmax scenario • background uncertainty: 10% • signal uncertainty included for exclusion • limited MC statistics for background also taken into account mhmax scenario mhmax scenario Preliminary Preliminary • most difficult region at intermediate tanb as coupling H+-tb smallest • if statistical uncertainties from limited MC neglected  gap closed

48. Charged Higgs Bosons high mass: mH+-> mtop gbH+-t H+-tn tbqq low mass: mH+-< mtop ggtt ttH+-bW only low lumi. new: Wqq H+-tn • transition region around mtop needs revised experimental analysis • running bottom quark mass used • Xsec for gbtH+- from T. Plehn‘s program

49. bbH, Httll 4n Preliminary • only >=1 btag analyis for now • mass resolution ~ 20% • low M: Ztt dominant background larger M: tt dominant BG • background estimate from data a la VBF • uncertainties considered: - exp. uncertainty: 5% signal 8% tt - Z background fom data (several %) - theo. uncertainty for signal: 20%(100 GeV) to 10%(400GeV) • other decays ttl had, had had and 0 btag analysis to come Preliminary

50. MSSM cross sections: neutral Higgs bosons LH03 hep-ph 0406152 • direct production: calculated with HIGLU • associated production: calculated with Harlander values for NNLO bb->H plus MSSM correction from Feynhiggs 2.6.2 • branching ratios calculated with Feynhiggs 2.6.2 • uncertainties: bbH 10% scales + 14%pdfs (MRST02/04) ggbbH 20-30%