lhc phenomenology: beyond the standard model · 2009. 12. 18. · if supersymmetry masses heavy...
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LHC Phenomenology:Beyond the Standard Model
James WellsCERN & MCTP
Durham, December 18, 2009
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Standard Model
Problem is that leptons and W,Z have mass.
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The Speculative Solution: Higgs Boson
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SM Higgs BosonEWSB accomplished by a single Higgs boson.
Higgs mass is only free parameter.
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Higgs mass limits
Higgs boson mass upper limit(95% CL) from precision Electroweak is less than 182 GeV.
Lower limit from lack ofdirect signal at LEP 2is about 115 GeV.
LEPEWWG
Experiment: 115 GeV < mh < 180 GeV
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Should we believe in the Higgs boson?
The Higgs boson is a speculative particle explanationfor elementary particle masses.
Cons:1. One particle carries all burdens of mass generation?2. Fundamental scalar not known in nature.3. Hasn’t been found yet.4. Too simplistic -- dynamics for vev not built in.5. Idea not stable to quantum corrections.
Pros: Still consistent with experimental facts!
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Higgs boson is very special…
The |H|2 operator is the only gauge-invariant,Lorentz invariant relevant operator in theStandard Model.
Other relevant operators include:Neutrino physics.
Lepton #Not in SM.Lorentz spinorLorentz Tensor
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Effective Theories
Expectation of Effective Theories:All operators receive O(1) coefficients unless there is asymmetry principle not to. (corollaries: ‘t Hooft’s naturalnessprinciples.)
Dimension=4 marginal operators: λ ~ 1
Dimension<4 relevant operators: Λ# ~ (Mpl)#
Higgs mass operator expected to be (Mpl)2|H|2unless there is a principle to forbid it.
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Related: Quadratic Sensitivity
A quantum loop is quadratically divergent. HiggsMass, connected to Higgs vev, is unstable to theHighest mass scales in the theory.
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Statics and Dynamics of Higgs Mass
Principle: SUSY, Xdim, Little Higgs, Compositeness, etc.
Top squarks, radion,T-odd top partners, etc. Gluinos, KK Gravitons, etc.
SUSY: +
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Minimal Supersymmetric Standard ModelMartin, hep-ph/9709356
If supersymmetry masses heavy (greater than all theSM masses), 4 Higgses {H+,H-,A,H} form a heavy, decoupled doublet,and h remains a light field, which behaves just as the Standard ModelHiggs boson.
Supersymmetry predicts mass of h field to be less thanAbout 135 GeV. I.e., compatible with data.Challenge: “Preference” for Higgs mass below expt bound.
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LHC Supersymmetry reach
CMS-TDR-008-2
CMSSM
Mbino ~ 0.4 m1/2Mwino ~ 0.8 m1/2Mgluino ~ 2.7 m1/2
Msquark2 ~ m02+5m2
1/2
Mstrong < few TeV~
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Large Extra DimensionsQuadratic divergence ok if no high scales
Extra Dimensions mayExplain large Planck Mass.(Arkani-Hamed, Dimopoulos, Dvali)
Drawings from Landsberg, 2001
Kaluza-Klein copies ofThe graviton accessibleAt high-energy colliders.(Giudice, Rattazzi, JW; Peskin, Perelstein, etc.)
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LHC Reach for KK Gravitons
Tevatron/LEP limits:Ms > 1.5 TeV
LHC expectations:Ms < ~ 5 TeVsensitivity
CMS-TDR-008-2
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Higgs Implications of Warped Extra Dimensions
Separation of the two branesat each point is a field T(x) --Radion Field.
The Radion interacts with SM Particles almost identically the sameas a Higgs boson, but with universally reduced couplings.
The radion and Higgs can mix through H*HR gravitationalcoupling, leading to no eigenstate that interacts with full expectedstrength. Giudice, Rattazzi, JDW, ‘01
(Randall, Sundrum)Graviton in warpedXdim space:KK Graviton
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KK Graviton Search in RS
CMS-TDR-008-2
c=0.01, 0.02, 0.05, 0.1 from top to bottom
KK Gravition
q
q
µ
µ
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Expectations and Opportunities
Data consistent with a rather light Higgs boson.
The entourage of states that protects and supportsthe Higgs boson should have mass close to it:Mnew ~ <H> [175 GeV] or (4π)1/2<H> [620 GeV] or 4π<H> [2.2 TeV] or ?
LHC in prime real estate todiscover the new dynamics --the entourage the makes theHiggs viable.
dailymail.co.uk
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New Opportunities with HiggsRelevant Operator
The |H|2 operator gives us a chance to see statesthat we could never have otherwise seen before.
Generic couplings of Higgs to SM singlets, hiddensectors, etc
(Generic coupling)
(Possible coupling with extra U(1)hid)
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Recall: Challenges of beingsensitive to New Physics
The Standard Model matter and gauge statessaturate dimensionality of the lagrangian.
Any new states coupled in may come with a largesuppression scale:
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Simple, Non-Trivial Hidden World
Probably simplest theory is a Hidden-SectorAbelian Higgs Model.
A complex scalar charged under U(1)X. The particlespectrum is a physical Higgs boson and an Xgauge field.
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LagrangianConsider the SM lagrangian plus the following:
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Canonical Kinetic TermsFirst, we make kinetic terms canonical by
The covariant derivative is shifted to
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Higgs Masses and Mixings
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Collider Searches for Z’
Kumar, JW 0606183
Undetectable
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Two Paths to LHC Discovery
Within this framework, we studied two ways to find Higgs boson at the LHC:
1) Narrow Trans-TeV Higgs boson signal
2) Heavy Higgs to light Higgs decays
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Narrow Trans-TeV Higgs Boson
When the mixing is small, the heavy Higgs hassmaller cross-section (bad), but more narrow (good).
Investigate Point C example
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Two Signals
1)
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H->WW->jjlν
H->WW(solid)
WWjj(dashed)
ttjj (dotted)
Between 1.0 &1.3 TeV 13signal events in100 fb-1 vs. 7.7bkgd
Techniques: Atlas & CMSTDRs and Iordanidis,Zeppenfeld, ‘97
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Difference from SUSY heavy Higgs boson
SUSY heavy Higgs has qualitatively different behavior:
Haber et al. ‘01
Heavy Higgs decaysmostly into tops orbottoms (or susypartners) dependingon tanβ.
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H decays to lighter Higgses
We can also have a heavier Higgs bosondecaying into two lighter ones in this scenario.
Both Higgses suppressed with respect to SM Higgs.
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Higgs discovery significancesCMS-TDR-008-2
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Heavy to Light Higgs rate
30 fb-1 bkgd estimates
Bowen, Cui, JW
Considered discovery mode (Richter-Was et al.):
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Light Higgs accidentally narrow
Light Higgs boson especially susceptible to new decay modes.
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Sources of Invisible DecayMany ideas lead to invisible Higgs decays -- possibleconnections to dark matter.
Simplest of all is the addition of a real scalar field with Z2.
S
S
H
Example from Abelian Higgs Model with fermions:
Joshipura et al. ‘93 ; Binoth, van der Bij, ‘97, etc.
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Invisible Higgs at LHC
Davoudiasl, Han, Logan, ‘05
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Light Z’ and Higgs DecaysWith tiny kinetic mixing, a very low Z’ mass is possiblein this framework. The light Higgs, however, couldcouple to it well with impunity. This leads to
H->Z’Z’ -> 4 leptons signature
H Z’
Z’
l+
l-
l’+
l’-Gopalakrishna, Jung, JW, ‘08
x
x
Z
Z
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ConclusionsHiggs boson is a unique object that is especially sensitive tonew physics.
New physics comes from its “viability entourage”:supersymmetry, extra dimensions, etc., all which affect Higgsboson collider phenomenology and add new TeV-scaledynamics.
New physics comes from its gauge- and Lorentz-invariantwindow to relevant operators, e.g. |H|2|Φ|2.
Collider physics alterations can show up very quickly at lowluminosity (e.g., Higgs to four lepton decays, light entourageparticles), and/or after much time (e.g., hidden sector fieldswith tiny mixings with the Higgs boson, heavy entourage)