measurements of higgs boson properties in...
TRANSCRIPT
Measurements of Higgs Boson Properties in ATLAS
Tim Adye Rutherford Appleton Laboratory
on behalf of the ATLAS Collaboration
Moriond QCD 14th March 2013
Higgs Boson Properties in ATLAS • “Observation of a new particle” in July 2012 • Update in December 2012 with additional luminosity • Today: updates for the full 2011-2012 dataset in decays to γγ, ZZ, WW
• 4.6 fb-1 @ 7TeV, 20.7 fb-1 @ 8TeV 1. Higgs mass measurement from H→γγ and H→ZZ(*)→4l 2. Signal strength of production and decay 3. Comparison of vector boson fusion (VBF) and gluon fusion (ggF)
production modes 4. Comparison of Higgs decay rates 5. Higgs couplings 6. (Higgs spin and parity)
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Higgs mass
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• High resolution mass measurements from H→γγ and H→ZZ(*)→4l spectra
• Combine γγ and 4l mass measurements • Signal strengths, μγγ and μ4l, allowed to
vary independently →Don’t assume SM couplings
• mH = 125.5 ± 0.2 stat −0.6+0.5 sys GeV
(4.8 fb-1 + 20.7 fb-1)
• Previous measurement, Dec 2012: • mH = 125.2 ± 0.3 (stat) ± 0.6 (sys) GeV
(4.8 fb-1 + 13 fb-1)
• Use profile likelihood ratio
Λ 𝑚𝑚𝐻𝐻 = 𝐿𝐿(𝑚𝑚𝐻𝐻,𝜃𝜃�� 𝑚𝑚𝐻𝐻 )𝐿𝐿(𝑚𝑚�𝐻𝐻,𝜃𝜃�)
to quantify mH confidence intervals with nuisance parameters, θ (μγγ, μ4l, theory, experimental systematics)
• Asymptotically, -2lnΛ distributed as a χ2
Update last week
Signal strength vs mass for γγ and ZZ
• Signal strength μ = σ/σSM vs mH contours for γγ and ZZ and their combination
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Comparison of masses from H→γγ and H→ZZ(*)→4l • The individual mass measurements, mγγ and m4l,
are slightly correlated due to the common EM scale systematic (for photons in mγγ and electrons in m4l) • Pulls mγγ down by 350 MeV in combined fit
• Test assumption that both decays come from a common mass • ΔmH = mγγ – m4l
= 2.3−0.7+0.6 stat ± 0.6 sys GeV
• Consistency ΔmH=0: • p-value = 1.5% (2.4σ) • More conservative E scale model: allow
systematics to vary without constraint ±1σ (rectangular PDF): p-value = 8% (1.7σ)
• Previous measurement, Dec 2012:
• ΔmH = 3.0 ± 0.8 stat −0.6+0.7 sys GeV
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m4l vs mγγ
Signal strength • Combination of
• W,Z H → bb (4.7 fb-1 + 13 fb-1)
• H → ττ (4.6 fb-1 + 13 fb-1)
• H → WW(*) → lνlν (4.6 fb-1 + 20.7 fb-1)
• H → γγ (4.8 fb-1 + 20.7 fb-1)
• H → ZZ(*) → 4l (4.6 fb-1 + 20.7 fb-1)
• Signal strength μ = σ/σSM measured assuming mH=125.5 GeV • Only ±4% change to combined μ for ±1 GeV
• Combined μ = 1.30 ± 0.13 (stat) ± 0.14 (sys) • Compatibility between measurements and SM (μ=1)
• Common μ vs SM: 9% • with rectangular QCD scale/PDF constraints: 40% • All μbb, μττ, μWW, μγγ, μZZ vs μ=1: 8% (5 d.o.f) • All μbb, μττ, μWW, μγγ, μZZ vs μ=1.30: 13% (4 d.o.f)
• ATLAS also sets limits (95%CL; not used in combination): • H → μμ: μ<9.8 (20.7 fb-1)
• H → Zγ: μ<18.2 (4.6 fb-1 + 20.7 fb-1)
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Update today!
Update last week!
Update last week!
New last week!
New last week!
Higgs production modes
• Dominant Higgs production modes expected from the SM at mH=125 GeV: 19.5 pb: gg fusion (ggF) 1.6 pb: vector boson fusion (VBF) – tagged with 2 jets in γγ, ZZ, and WW analyses 1.1 pb: W,Z + H (VH) – W,Z tagged in γγ, ZZ, and bb analyses 0.1 pb: tt + H (ttH)
• Group together production signal strengths: • Fermion-mediated: μggF+ttH ≡ μggF = μttH • Boson-mediated: μVBF+VH ≡ μVBF = μVH
– ttH,VH rates subdominant
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ggF VBF
ttH VH
VBF
VH ttH
VBF and ggF production modes • μVBF+VH vs μggF+ttH
• Measured yields in different production modes could be modified by B/BSM
• May be different for each decay mode
• Ratio μVBF+VH / μggF+ttH
• B/BSM cancels out in each decay mode • Can compare / combine different modes
• μVBF+VH / μggF+ttH = 1.2−0.5+0.7
• Also test for VBF alone (profile μVH):
• p-value of μVBF / μggF+ttH=0: 0.09% (3.1σ) (1-sided)
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Compatible with SM
Evidence for VBF
• Can also test decays in a fairly model-independent way
• Relative ratios of branching ratios, eg.
• 𝜌𝜌𝛾𝛾𝛾𝛾/ZZ = 1.1−0.3+0.4
• 𝜌𝜌𝛾𝛾𝛾𝛾/WW = 1.7−0.5+0.7
• 𝜌𝜌ZZ/WW = 1.6−0.5+0.8
Higgs decays
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γγ/ZZ γγ/WW ZZ/WW
Note: only two ratios independent
All compatible with SM
Higgs couplings • For each observed final state, production and decay involve several couplings • Test SM by applying scale factors κi to each coupling and fitting for κis
• Assume a single resonance with a mass near 125 GeV • Test at 125.5 GeV (varying mass hypothesis is a small effect)
• Assume narrow resonance (σ·BR(ii→H→ff) ≈ σii·Γff / ΓH) • Only test modifications to the magnitude of the couplings (=> CP even scalar)
• Not all couplings accessible with current data, so test specific scenarios • Benchmark models defined by the LHC-XS-WG
• Eg. H→γγ:
• where κg and κγ are effective scale factors on the loop couplings • functions of κt, κb, κW,...
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Note: interference
Fermion vs Vector couplings
• Model: • Vector and fermion couplings grouped
together • κV ≡ κW = κZ [SM: κV=κF=1] • κF ≡ κt = κb = κτ = κg
• Assume only SM particles contribute to κg (gg→H, via fermion loop) and κγ (H→γγ)
• This assumption can be relaxed – see backup slides
• Some sensitivity to relative sign due to H→γγ interference term
• κV = [0.91, 0.97] and [1.05, 1.21] (68% CL) • κF = [-0.88, -0.75] and [0.73, 1.07]
• 2D Compatibility with SM: 8%
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Contribution of individual channels
κF vs κV
Custodial symmetry: W vs Z couplings
• Model: • Ratio of W/Z couplings, fermion couplings grouped together, total width left free • λWZ ≡ κW / κZ [SM: λWZ=λFV=κZZ=1] • λFZ ≡ κF / κZ (profiled in fit)
• κZZ ≡ κZκZ / κH (profiled in fit) • Assume loops contain only SM particles
• Can relax assumption on H→γγ loop content – see backup slides
• λWZ = [0.64, 0.87] (68% CL)
• 3D compatibility with SM: 5%
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λWZ (λFZ, κZZ profiled)
Fit prefers λFZ<0 minimum
compatible with λFZ>0 at 1.5σ
Non-SM particle content in gg→H and H→γγ loops
• Model: • Test for non-SM particle content in gg→H (κg) and H→γγ (κγ) loops • Assume all tree-level couplings as in SM (κW=κZ=κt=...=1) and no extra SM
contributions to the total width (κH) • Parameters: κg and κγ [SM: κg=κγ=1]
• κg = 1.08 ± 0.14 • κγ = 1.23−0.13
+0.16
• 2D compatibility with SM: 5%
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κg vs κγ
Non-SM decay modes
• Model: • Assume all SM vertex couplings (κi=1) and test for invisible or undetectable
non-SM decay modes
• BRinv,undet = 1 − κH2
ΓH/ΓHSM [SM: κg=κγ=1, BRinv,undet=0]
• Profile κg and κγ
• BRinv,undet < 0.6 (95% CL)
• 3D compatibility with SM: 10% • ATLAS also has a dedicated search for
Z H → invisible (missing ET): • BRinv < 0.65 (95% CL)
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BRinv,undet (κg,κγ profiled)
New last week!
Summary of coupling results
• Overall compatibility with SM: 5-10% • No significant deviation from SM
• Note: each model is a different way of
fitting the same data • correlated, so don’t add them up!
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Conclusion
• mH = 125.5 ± 0.2 stat −0.6+0.5 sys GeV
• μ = 1.30 ± 0.13 (stat) ± 0.14 (sys)
• μVBF+VH / μggF+ttH = 1.2−0.5
+0.7 • 3.1σ evidence for VBF production
• Higgs couplings consistent with SM
• Spin and parity (from Eleni’s talk):
• compatible with 0+
• start to exclude 2+m in γγ and WW,
and 0–, 1+ in ZZ
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BACKUP
References • Higgs couplings: ATLAS-CONF-2013-XXX • Higgs mass: ATLAS-CONF-2013-014
• γγ: ATLAS-CONF-2013-012, spin: ATLAS-CONF-2013-029 • ZZ: ATLAS-CONF-2013-013 • WW: ATLAS-CONF-2013-030, spin: ATLAS-CONF-2013-031 • ττ: ATLAS-CONF-2012-160 (Nov 2012) • bb: ATLAS-CONF-2012-161 (Nov 2012) • μμ: ATLAS-CONF-2013-010 • Zγ: ATLAS-CONF-2013-009 • ZH→invisible: ATLAS-CONF-2013-011
• Previous combination: ATLAS-CONF-2012-170 (Dec 2012) • Previous coupling results: ATLAS-CONF-2012-127 (Sep 2012) • Observation: Phys. Lett. B 716 (2012) 1-29 (July 2012)
• LHC XS WG coupling recommendations: arXiv:1209.0040
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p0 vs mH hypothesis • Update of combined p0
• Mass scale systematics taken into account • primarily of interest during discovery phase
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H→ZZ(*)→4l individual channel mass measurements
▬ 4μ ▬ 4e ▬ 2e2μ ▬ 2μ2e
▬ Solid: with mass scale systematics ▬ Dashed: without mass scale systematics
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Fermion vs Vector couplings no assumption on total width
• Model:
• Ratio of fermion/vector couplings with no assumption on the total width • λFV ≡ κF / κV [SM: λFV=κVV=1] • κVV ≡ κVκV / κH (profiled in fit)
• λFV = [-0.94, -0.80] and [0.67, 0.93] (68% CL)
• 2D compatibility with SM: 7%
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λFV (κVV profiled)
Fermion vs Vector couplings no assumption on total width or H→γγ loop content
• Model:
• Ratio of fermion/vector couplings with no assumption on the total width or H→γγ loop content
• λFV ≡ κF / κV [SM: λFV=λγV=κVV=1] • λγV ≡ κγ / κV (profiled in fit)
• κVV ≡ κVκV / κH (profiled in fit)
• λFV = 0.85−0.13+0.23
• 3D compatibility with SM: 9%
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λFV (λγV, κVV profiled)
Custodial symmetry: W vs Z couplings no assumption on H→γγ loop content
• Model:
• Ratio of W/Z couplings with no assumption on H→γγ loop content • λWZ ≡ κW / κZ [SM: λWZ=λFV=λγZ=κZZ=1] • λFZ ≡ κF / κZ (profiled in fit) • λγZ ≡ κγ / κZ (profiled in fit)
• κZZ ≡ κZκZ / κH (profiled in fit)
• λWZ = 0.80 ± 0.15
• 4D compatibility with SM: 9%
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λWZ (λFZ, λγZ, κZZ profiled)
Summary of coupling results - detail
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• Overall compatibility with SM: 5-10% • No significant deviation from SM
• Note: each model is a different way of
fitting the same data • correlated, so don’t add them up!
Higgs spin: H → γγ • Compare spin 0+ (SM) to a 2+
m model (graviton-like with minimal couplings)
• Observation of H→γγ already excludes spin 1
• Use θ* in Higgs rest frame to discriminate • Compared to 0+, can exclude 2+ at 99.3%
(assuming 100% gg-production)
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• Compare spin 0+ (SM) to 0–, 1±, 2± models • Use 5 production and decay angles to form two alternative discriminants:
• Multivariate (BDT) • Matrix element likelihood ratio (JP-MELA)
• Spin 0+ hypothesis favoured over 0–, 1+
• Cannot yet distinguish well spin 0+ from, spin 2
Higgs spin and parity: H → ZZ(*) → 4l
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Higgs spin: H → WW(*) → lνlν • Compare spin 0+ (SM) to a 2+
m model (graviton-like with minimal couplings)
• Use m║, pT║, Δφ║, and mT to form a BDT
discriminant • Compared to 0+, can exclude 2+ at 95-99%
(depending on qq production fraction)
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