andrei gritsan johns hopkins university · 2016. 10. 18. · higgs at lhc: h → zz → 2l2q...
TRANSCRIPT
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Status of LHC and the Higgs Search
Andrei Gritsan
Johns Hopkins University
August, 2011
JHU Quarknet Meeting
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Finding the Higgs
• Higgs mechanism is responsible for
generating mass of fundamental particles
(discuss later how)
• Is it responsible for our mass?
(discuss later why)
• Why have not we seen the Higgs ?
(A) it is too heavy for past experiments
(B) it does not exist
• If Higgs is so important:
– how do we find the Higgs ?
– or prove that it does not exist...Andrei Gritsan, JHU August, 2011
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Produce the Higgs: Reaching Highest Energy
• mc2 = E
Andrei Gritsan, JHU August, 2011
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Large Hadron Collider: Running at Full Speed
Andrei Gritsan, JHU August, 2011
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CMS Experiment
Andrei Gritsan, JHU August, 2011
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Detecting Particles at CMS
Andrei Gritsan, JHU August, 2011
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Production of the Higgs
• Higgs interaction strength ∝ mass of particles
of color-neutral& charge-neutral Higgs
• Does not interact with
massless gluons directly
gg→ X
only through a ”loop”
• Very unlikely to interact with
light quarks in proton
qq̄ → X
negligible
Andrei Gritsan, JHU August, 2011
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Decay of the Higgs
• Consider decay back to Standard Model particles
• Decay to fermions
X → l+l−, qq̄
again very unlikely (light)
• Decay to gauge bosons
X → γγ, W+W−, ZZ, gg
γγ trough a loop
two likely channels WW , ZZ
but Higgs mass >∼ 2mW
Andrei Gritsan, JHU August, 2011
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Next Steps
• If there is a Higgs
– likely to appear as a ”resonance” on top of ”background”
– ”background” = random combination of particles
ZZ mass [GeV]200 250 300 350
N e
vent
s/2
GeV
0
5
10
15
20 µBkg 4
Bkg 4e
µBkg 2e2
µRSG 250 GeV, 4
RSG 250 GeV, 4e
µRSG 250 GeV, 2e2
Andrei Gritsan, JHU August, 2011
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Cartoon of an Experiment
Andrei Gritsan, JHU August, 2011
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Kinematics of X → ZZ and WW
• We can describe kinematics of decay and distinguish from others
Andrei Gritsan, JHU August, 2011
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Higgs at LHC
• By the end of June 2011 collected ∼1 fb−1 of data
∼ 100 trillion proton-proton collisions
for comparison, in 2010 we had ∼0.04 fb−1
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: Candidate Events H → ZZ
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: Candidate Events H → ZZ
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: Candidate Events H → ZZ
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: Candidate Events H → ZZ
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: Candidate Events H → ZZ
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: Candidate Events H → ZZ
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: Candidate Events H → ZZ
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: Candidate Events H → ZZ
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: H → ZZ → 4l
• Perform statistical analysis of observed events
– data are consistent with background only
– can try to reject Higgs at 95% confidence
]2 [GeV/c4lM100 200 300 400 500 600
2E
vent
s/10
GeV
/c
-210
-110
1
DATA
Z+jets
ZZ
2=250 GeV/cHm
2=200 GeV/cHm
2=150 GeV/cHm
CMS Preliminary 2011 -1 = 7 TeV L = 1.13 fbs
]2 [GeV/cHM200 300 400 500 600
SM
σ/σ95
% C
L lim
it on
0
5
10
15
20
25 Observed LimitSCL
Expected LimitSCL
σ 1± Expected SCL
σ 2± Expected SCL
SMσ / σ
CMS preliminary 2011 = 7 TeVs at -11.13 fb
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: H → ZZ → 2l2q
• Perform statistical analysis of observed events
– data are consistent with background only
– can try to reject Higgs at 95% confidence
[GeV]ZZm200 300 400 500 600 700
Eve
nts
/ 20
GeV
0
20
40
60
80
100
120
140
-1CMS Preliminary 2011, 1.0 fb = 7 TeVs
Sideband Extrapolated Fit
0 b-tag 2l2q data
Z + Jets
tt/tW
ZZ/WZ/WW
3×400 GeV SM Higgs
[GeV]HM250 300 350 400 450 500 550 600
SM
σ /
95%
σ
0
2
4
6
8
10
12
14
16
18
20 ObservedSCL ExpectedSCL
σ 1± Expected SCLσ 2± Expected SCL
SM
CMS preliminary 2011 = 7 TeVs at -11.0 fb
Andrei Gritsan, JHU August, 2011
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Higgs at LHC: Combine All Channels
• Combine all Higgs channels
– Higgs→ γγ, ττ,WW,ZZ, with ZZ → 4l, 2l2q, 2l2ν
– reject Higgs at 95% confidence in large range of masses
Andrei Gritsan, JHU August, 2011
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Closing on the Higgs
• We are excluding large range of masses now
• Preparing new results by mid-August, LHC performs well
• Even better by the end of 2011, and in 2012
• We will either FIND or REJECT the SM Higgs hypothesis
– both options are exciting
– both will be only the first step to explain puzzles
(1) if Higgs found, still new discoveries expected to explain
incosistencies of the model
(2) if Higgs not found, even more expected to explain the
mechanism of mass
Andrei Gritsan, JHU August, 2011
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What is the Higgs Particle?
• This answer is probably not very satisfying to see first:
Higgs appears from introduction of this Lagrangian
in the quantum field theory of particles
L =1
2(∂µφ)2 −
1
2µ2φ2 +
1
4λφ4
-1.5 -1 -0.5 0 0.5 1 1.5
-0.2
0
0.2
0.4
0.6
0.8
1
Andrei Gritsan, JHU August, 2011
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What is Higgs?
• There are several phenomena:
– Peter Higgs
– Higgs mechanism
– Higgs field
– Higgs particle (still elusive particle)
• People sometimes confuse these phenomena
– especially the last two
• So far there is hard evidence only for the first:
– 1964 article by Peter Higgs in Physics Review Letters
Andrei Gritsan, JHU August, 2011
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Why is it Higgs Mechanism ?
• In fact, there are several names of the Higgs mechanism:
– Brout-Englert-Higgs mechanism
– Higgs-Brout-Englert-Guralnik-Hagen-Kibble mechanism
– Anderson-Higgs mechanism
– Higgs mechanism is just simpler
– all for authors of independent papers on the topic
• Partly due to ironic history with the paper by Higgs:
– rejected from European Physics Letters
“of no obvious relevance to physics”
– added a paragraph predicting a new particle
Andrei Gritsan, JHU August, 2011
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Spontaneous Symmetry Breaking• Spontaneous symmetry breaking → Higgs mechanism
• 3 quark families → matter over antimatter asymmetry
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Spontaneous Symmetry Breaking
• Symmetry spontaneously broken: pick φ = vat minimum of potential energy of Higgs field (µ2 < 0)
V (φ1, φ2, φ3, φ4) =1
2µ2
[
φ21 + φ2
2 + φ23 + φ2
4
]
+1
4λ [...]2
1φ
-1 -0.5 0 0.5 12φ
-1-0.50
0.51
-0.2
-0.1
0
0.1
0.2
0.3
-1.5 -1 -0.5 0 0.5 1 1.5
-0.2
0
0.2
0.4
0.6
0.8
1
• Higgs particle described by one field component
η = φ1 − v
Andrei Gritsan, JHU August, 2011
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What about other Higgs field components?
• The other field components φ2, φ3, φ4 “couple”
to Weak Interaction bosons Z, W − , W +
and give them mass
• Photon γ is the same Weak Interaction boson
but remains massless (does not couple to Higgs field)
Andrei Gritsan, JHU August, 2011
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All Elementary Particles get Mass from Higgs Field
• Fermions S = h̄2
(matter)
leptons
quarks
(anti-matter)
• Bosons S = h̄ (force carries):
← massless
(weak force bosons mass)
EM strong
Andrei Gritsan, JHU August, 2011
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What is Higgs?• Higgs mechanism
– existence of Higgs field
– spontaneous symmetry breaking and “gauge” invariance
(interaction with Z,W±)
– gives mass to all elementary particles
– predicts existence of Higgs particle
• Everything works perfectly, except:
– we have not observed the Higgs particle yet
• Why: – Higgs particle is too heavy to produce (if it exists)
(more than 100× proton mass)
– hope to produce or exclude at Large Hadron Collider
– still possible that Higgs mechanism is not correct
Andrei Gritsan, JHU August, 2011
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Do we have mass due to Higgs mechanism?
• Yes and no
– we are not elementary particles...
Andrei Gritsan, JHU August, 2011
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What does give us mass? Molecules? Atoms?
Andrei Gritsan, JHU August, 2011
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What does make mass?
• What gives us mass?
Molecules Atoms Nucleus
Andrei Gritsan, JHU August, 2011
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“Periodic Table” of Baryons: Proton, Neutron,...
• Three quarks make up a Baryon:
Andrei Gritsan, JHU August, 2011
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What Gives Mass to Baryons: Proton, Neutron,...
• Remember Einstein’s formula
E = mc2
m(u or d) < 1% m(proton)
Mostly energy of gluons and quarks inside gives proton mass
not really the Higgs mechanism
Andrei Gritsan, JHU August, 2011
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But Higgs Mechanism is Very Important
• Makes Weak Interactions weak: mass of Z,W−,W+
similarly first step in sun fusion
p + p→ d + e+ + νe
• Makes certain hierarchy of masses
essential for our existence
Andrei Gritsan, JHU August, 2011
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Hypothetical Scenario: Different Quark Mass
• Again, normally proton is stable and neutron decays:
m(n) > m(p) + m(e) + m(νe)
• Why is m(n) > m(p)
– m(p) = 938 MeV, m(n) – m(p) = 1.3 MeV
– tiny difference makes a big difference!
– naively expect m(p) > m(n) if u and d were the same
– but m(d) > m(u)
• New scenario:
– what if m(d) < m(u)
Andrei Gritsan, JHU August, 2011
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Hypothetical Scenario: Different Quark Mass
• If m(d) < m(u), proton decays:
• Consequence: no Hydrogen, no H20, no life
– still have He4, rapid nn fusion, instead of slower pp
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We are likely to find more than just Higgs
• New (super)symmetry:
Q|fermion〉=|boson〉
Q|boson〉=|fermion〉
• Solve:
(1) natural light
H iggs
(2) dark matter
lightest χ̃01
(3) large matter/antimatter
• Just around the corner in mass...Andrei Gritsan, JHU August, 2011
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BACKUP SLIDES
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(1) Another Scenario: Muonic World
• We would get a muonic atom:
• Size changes:
radius r = 4πǫ0h̄2
mµe2 , 200 smaller !
Hydrogen radius
r = 4πǫ0h̄2
mee2 = 5× 10−11 mAndrei Gritsan, JHU August, 2011
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(1) Scenario: Muonic World
• However muonic hydrogen would decay:
• Not very interesting universe
– filled with neutral “balls” of neutrons and neutrinosAndrei Gritsan, JHU August, 2011
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(1) Scenario: Muonic World
• Normally neutron is not stable (life τ ∼ 886 seconds)
m(n) > m(p) + m(e) + m(νe)
• But stable in the muonic world:
m(n) < m(p) + m(µ) + m(νµ)Andrei Gritsan, JHU August, 2011
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Andrei Gritsan, JHU August, 2011
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Andrei Gritsan, JHU August, 2011
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Look Beyond the Standard Model
• Why does matter dominate (Sakharov):
– CP -asymmetry
– baryon non-conservation
– non-equilibrium
• Mysterious H iggs field
– gives mass to particles
• Need something beyond the SM
– large CP -asymmetry
– dark matter
– light H iggs 0
1
2
3
4
5
6
10030 300
mH [GeV]∆χ
2
Excluded
∆αhad =∆α(5)
0.02758±0.00035
0.02749±0.00012
incl. low Q2 data
Theory uncertainty
Andrei Gritsan, JHU August, 2011