theory of proton-proton · pdf filessi 2006 4 past, present and future proton/antiproton...
TRANSCRIPT
Theory of Proton-Proton Collisions
James StirlingIPPP, Durham University
SSI 2006 2
references
“QCD and Collider Physics”
RK Ellis, WJ Stirling, BR WebberCambridge University Press (1996)
also
“Handbook of Perturbative QCD”
G Sterman et al (CTEQ Collaboration)www.phys.psu.edu/~cteq/
SSI 2006 3
… and
“Hard Interactions of Quarks and Gluons: a Primer for LHC Physics ”
JM Campbell, JW Huston, WJ Stirling (CSH)
www.pa.msu.edu/~huston/seminars/Main.pdf
to appear in Rep. Prog. Phys.
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past, present and future proton/antiproton colliders…
Tevatron (1987→)Fermilab
proton-antiproton collisions√S = 1.8, 1.96 TeV
LHC (2007 → )CERNproton-proton and heavy ion collisions√S = 14 TeV
SppS (1981 → 1990)CERNproton-antiproton collisions√S = 540, 630 GeV
-
discoveries
1970 1980 1990 2000 20202010
tc b W,Z H, SUSY?
Higgs discovery at LHC
SUSY discovery at LHC
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Scattering processes at high energy hadron colliders can be classified as either HARD or SOFT
Quantum Chromodynamics (QCD) is the underlying theory for all such processes, but the approach (and the level of understanding) is very different for the two cases
For HARD processes, e.g. W or high-ET jet production, the rates and event properties can be predicted with some precision using perturbation theory
For SOFT processes, e.g. the total cross section or diffractive processes, the rates and properties are dominated by non-perturbative QCD effects, which are much less well understood
What can we calculate?
Outline• Basics: QCD, partons, pdfs
– basic parton model ideas for DIS– scaling violation & DGLAP– parton distribution functions
• Application to hadron colliders– hard scattering & basic kinematics– the Drell Yan process in the parton model– order αS corrections to DY, singularities, factorisation– examples of other hard processes and their phenomenology – parton luminosity functions – uncertainties in the calculations
• Beyond fixed-order inclusive cross sections– Sudakov logs and resummation– parton showering models (basic concepts only!)– the role of non-perturbative contributions: intrinsic kT,– underlying event/minimum bias contributions– theoretical frontiers: exclusive production of Higgs
Basics of QCD
• renormalisation of the coupling
• colour matrix algebra
0
1
μ (GeV)
αS(μ)
perturbative
non-perturbative
quark quark
αS = gS2/4π
gluongluon
gluon
gS Taij
gluon
gS fabc
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Asymptotic Freedom
“What this year's Laureates discovered was something that, at first sight, seemed completely contradictory. The interpretation of their mathematical result was that the closer the quarks are to each other, the weaker is the 'colour charge'. When the quarks are really close to each other, the force is so weak that they behave almost as free particles. This phenomenon is called ‘asymptotic freedom’. The converse is true when the quarks move apart: the force becomes stronger when the distance increases.”
1/r
αS(r)
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deep inelastic scattering and the parton model
qμ
pμ
X
electron
proton
• variablesQ2 = –q2 (resolution)
x = Q2 /2p·q (inelasticity)
• structure functionsdσ/dxdQ2 ∝ α2 Q-4 F2(x,Q2)• (Bjorken) scalingF2(x,Q2) → F2(x) (SLAC, ~1970)
0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.80.0
0.2
0.4
0.6
0.8
1.0
1.2
Q2 (GeV2) 1.5 3.0 5.0 8.0 11.0 8.75 24.5 230 80 800 8000
F 2(x,Q
2 )
Bjorken 1968
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• photon scatters incoherently off massless, pointlike, spin-1/2 quarks
• probability that a quark carries fraction ξ of parent proton’s momentum is q(ξ), (0< ξ < 1)
the parton model (Feynman 1969)
• the functions u(x), d(x), s(x), … are called parton distribution functions (pdfs) - they encode information about the proton’s deep structure
...)(91)(
91)(
94
)()()()( 2
,
21
0,
2
+++=
=−= ∑∫∑
xsxxdxxux
xqxexqedxF qqq
qqq
ξδξξξ
infinitemomentumframe
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extracting pdfs from experiment• different beams
(e,μ,ν,…) & targets (H,D,Fe,…) measure different combinations of quark pdfs
• thus the individual q(x)can be extracted from a set of structure function measurements• gluon not measured directly, but carries about 1/2 the proton’s momentum
[ ][ ]...2
...2
...)(91)(
94)(
91
...)(91)(
91)(
94
2
2
2
2
+++=
+++=
++++++=
++++++=
sduF
usdF
ssdduuF
ssdduuF
n
p
en
ep
ν
ν
( ) 55.0)()(1
0=+∫∑ xqxqxdx
q
eNN FFss 22 365
−== ν
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35 years of Deep Inelastic Scattering
0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.80.0
0.2
0.4
0.6
0.8
1.0
1.2
Q2 (GeV2) 1.5 3.0 5.0 8.0 11.0 8.75 24.5 230 80 800 8000
F 2(x,Q
2 )
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(MRST) parton distributions in the proton
10-3 10-2 10-1 1000.0
0.2
0.4
0.6
0.8
1.0
1.2
MRST2001
Q2 = 10 GeV2
up down antiup antidown strange charm gluon
x
f(x,
Q2 )
x Martin, Roberts, S, Thorne
HERA
e+, e− (28 GeV) p (920 GeV)
electron proton
quark
a deep inelastic scattering event at HERA
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35 years of Deep Inelastic Scattering
0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.80.0
0.2
0.4
0.6
0.8
1.0
1.2
Q2 (GeV2) 1.5 3.0 5.0 8.0 11.0 8.75 24.5 230 80 800 8000
F 2(x,Q
2 )
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scaling violations and QCD
quarks emit gluons!0.0 0.2 0.4 0.6 0.8 1.0
0
2
4
6
x
F2
Q1
Q2 > Q1
The structure function data exhibit systematic violations of Bjorken scaling:
++ + …+
where the logarithm comes from(‘collinear singularity’) and
then convolute with a ‘bare’ quark distribution in the proton:
p xp
q0(x)
next, factorise the collinear divergence into a ‘renormalised’quark distribution, by introducing the factorisation scale μ2 :
then finite, by construction
note arbitrariness of ‘factorisation scheme dependence’
q(x,μ2) is not calculable in perturbation theory,* but its scale (μ2)dependence is: Dokshitzer
GribovLipatovAltarelliParisi
*lattice QCD?
we can choose C such that Cq= 0, the DIS scheme, or use dimensional regularisation and remove the poles at N=4, the MS scheme, with Cq ≠ 0
___
note that we are free to choose μ2 = Q2 in which case
… and thus the scaling violations of the structure function follow those of q(x,Q2) predicted by the DGLAP equation:
coefficient function,see QCD book
0.0 0.2 0.4 0.6 0.8 1.00
2
4
6
x
F 2
Q1
Q2 > Q1
q
the rate of change of F2 is proportional to αS(DGLAP), hence structure function data can be used to measure the strong coupling!
however, we must also includethe gluon contribution
… and with additional terms in the DGLAP equations
splittingfunctions
note that at small (large) x, the gluon (quark) contribution dominates the evolution of the quark distributions, and therefore of F2
coefficient functions- see QCD book
DGLAP evolution: physical picture• a fast-moving quark loses momentum by emitting a gluon:
• … with phase space kT2 < O(Q2 ), hence
• similarly for other splittings
• the combination of all such probabilistic splittings correctly generates the leading-logarithm approximation to the all-orders in pQCD solution of the DGLAP equations
kTp ξp
Altarelli, Parisi (1977)
basis of parton shower Monte Carlos!
• the bulk of the information on pdfs comes from fitting DIS structure function data, although hadron-hadron collisions data also provide important constraints (see later)
• pdfs are useful in two ways:– they are essential for predicting hadron collider cross sections, e.g.
– they give us detailed information on the quark flavour content of the nucleon
• no need to solve the DGLAP equations each time a pdf is needed; high-precision approximations obtained from ‘global fits’ are available ‘off the shelf”, e.g.
parton distribution functions
Hp p
input | output
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how pdfs are obtained
• choose a factorisation scheme (e.g. MSbar), an order in perturbation theory (see below, e.g. LO, NLO, NNLO) and a ‘starting scale’ Q0 where pQCD applies (e.g. 1-2 GeV)
• parametrise the quark and gluon distributions at Q0,, e.g.
• solve DGLAP equations to obtain the pdfs at any x and scale Q > Q0 ; fit data for parameters {Ai,ai, …αS}
• approximate the exact solutions (e.g. interpolation grids, expansions in polynomials etc) for ease of use
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pdfs from global fits - summary
Who?CTEQ, MRST, Alekhin,H1, ZEUS, …
http://durpdg.dur.ac.uk/hepdata/pdf.html
DataDIS (SLAC, BCDMS, NMC, E665,CCFR, H1, ZEUS, … )Drell-Yan (E605, E772, E866, …)High ET jets (CDF, D0)W rapidity asymmetry (CDF,D0)νN dimuon (CCFR, NuTeV)etc.
fi (x,Q2) ± δ fi (x,Q2)
αS(MZ )
FormalismLO, NLO or NNLO DGLAPMSbar factorisationQ0
2
functional form @ Q02
sea quark (a)symmetryetc.
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(MRST) parton distributions in the proton
10-3 10-2 10-1 1000.0
0.2
0.4
0.6
0.8
1.0
1.2
MRST2001
Q2 = 10 GeV2
up down antiup antidown strange charm gluon
x
f(x,
Q2 )
x Martin, Roberts, S, Thorne
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where to find parton distributions
HEPDATA pdf websitehttp://durpdg.dur.ac.uk/hepdata/pdf.html
• access to code for MRST, CTEQ etc
• online pdf plotting
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1972-77 1977-80 2004
going to higher orders in pQCD is straightforward in principle, since the above structure for F2 and for DGLAP generalises in a straightforward way:
The calculation of the complete set of P(2) splitting functions by Moch, Vermaseren and Vogt (hep-ph/0403192,0404111) completes the calculational tools for a consistent NNLO pQCD treatment of Tevatron & LHC hard-scattering cross sections!
beyond lowest order in pQCD
see above see book see next slide!
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7 pages later…
Moch, Vermaseren and Vogt, hep-ph/0403192, hep-ph/0404111
• and for the structure functions…
… where up to and including the O(αS3) coefficient
functions are known
• terminology:– LO: P(0)
– NLO: P(0,1) and C(1)
– NNLO: P(0,1,2) and C(1,2)
• the more pQCD orders are included, the weaker the dependence on the (unphysical) factorisation scale, μF
2
– and also the (unphysical) renormalisation scale, μR2 ; note above has μR
2 = Q2
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Scattering processes at high energy hadron colliders can be classified as either HARD or SOFT
Quantum Chromodynamics (QCD) is the underlying theory for all such processes, but the approach (and the level of understanding) is very different for the two cases
For HARD processes, e.g. W or high-ET jet production, the rates and event properties can be predicted with some precision using perturbation theory
For SOFT processes, e.g. the total cross section or diffractive processes, the rates and properties are dominated by non-perturbative QCD effects, which are much less well understood
What can we calculate?
for inclusive production, the basic calculational framework is provided by the QCD FACTORISATION THEOREM:
higher-order pQCD corrections; accompanying radiation, jets
parton distribution functions
underlying event
X = W, Z, top, jets,SUSY, H, …
p
p
hard scattering in hadron-hadron collisions
kinematics
• collision energy:
• parton momenta:
• invariant mass:
• rapidity:
x1P
proton
x2P
proton
M
10-7 10-6 10-5 10-4 10-3 10-2 10-1 100100
101
102
103
104
105
106
107
108
109
fixedtargetHERA
x1,2 = (M/1.96 TeV) exp(±y)Q = M
Tevatron parton kinematics
M = 10 GeV
M = 100 GeV
M = 1 TeV
422 04y =
Q2
(GeV
2 )
x10-7 10-6 10-5 10-4 10-3 10-2 10-1 100
100
101
102
103
104
105
106
107
108
109
fixedtargetHERA
x1,2 = (M/14 TeV) exp(±y)Q = M
LHC parton kinematics
M = 10 GeV
M = 100 GeV
M = 1 TeV
M = 10 TeV
66y = 40 224Q
2 (G
eV2 )
x
x1P
proton
x2P
proton
M
DGLAP evolution
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early history: the Drell-Yan process
μ+
μ-
γ*quark
antiquark
τ = Mμμ2/s
“The full range of processes of the type A + B →μ+μ- + X with incident p,π, K, γ etc affords the interesting possibility of comparing their parton and antiparton structures” (Drell and Yan, 1970)
(nowadays) … and to study the scattering of quarks and gluons, and how such scattering creates new particles
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jets! (1981)
jet
jet
antiprotonproton
e.g. two gluons scattering at wide angle
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factorisation• the factorisation of ‘hard scattering’ cross sections into products of parton
distributions was experimentally confirmed and theoretically plausible• however, it was not at all obvious in QCD (i.e. with quark–gluon
interactions included)
μ+
μ-
γ*
• in QCD, for any hard, inclusive process, the soft, nonperturbative structure of the proton can be factored out & confined to universal measurable parton distribution functions fa(x,μF
2) Collins, Soper, Sterman (1982-5)
and evolution of fa(x,μF2) in factorisation scale calculable using the DGLAP
equations, as we have seen earlier
Log singularities from soft and collinear gluon emissions
Drell-Yan in more detailμ+
μ-
γ*quark
antiquark
scaling!
also
beyond leading order …
++++ + …+
Note:• collinear divergences, with same coefficients of logs as in DIS: P(x)• finite correction: fq(x)• introduce a factorisation scale, as before:
• then fold the parton-level cross section with q0(x1) and q0(x2), and with the same ‘renormalised’ distributions as before*, we obtain
• the standard scale choice is μ=M
finiteAltarelli et alKubar et al1978-80*
Note:• the full calculation at O(αS) also includes
• which gives rise to αS q * g terms in the cross section (see QCD book)
• the (finite) correction is sometimes called the ‘K-factor’, it is generally large and positive
• … and is factorisation scheme/scale dependent (to compensate the scheme dependence of the pdfs)
+
using high-precision Drell-Yan data to constrain the sea-quark pdfs
Note: MRST
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Anastasiou, Dixon, Melnikov, Petriello (hep-ph/0306192)
the asymmetric sea
10-2 10-1 1000.00
0.25
0.50
0.75
1.00
1.25
1.50
1.75
2.00
MRST2001
Q2 = 10 GeV2
ant
idow
n / a
ntiu
p
x
• the sea presumably arises when ‘primordial‘valence quarks emit gluons which in turn split into quark-antiquark pairs, with suppressed splitting into heavier quark pairs
• so we naively expect
• why such a big d-u asymmetry? meson cloud, Pauli exclusion, …?
• and is ?
The ratio of Drell-Yan cross sections for pp,pn → μ+μ- + X provides a measure of the difference between the u and d sea quark distributions
W, Z cross sections: Tevatron and LHC
NNLO QCD
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
CDF(e, μ) D0(e, μ)
NNLONLO
LO
Tevatron (Run 2)
Z(x10)W
CDF(e, μ) D0(e, μ)
σ . B
l (n
b)
partons: MRST2004
14
15
16
17
18
19
20
21
22
23
24
partons: MRST2004
W
NLONNLO
LO
LHC Z(x10)
σ . B
l (n
b)
parton level cross sections (narrow width approximation)
+ pQCD corrections to NNLO, EW to NLO
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Anastasiou, Dixon,Melnikov, Petriello
Z rapidity distributionat the Tevatron
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Drell-Yan as a probe of new physicsLarge Extra Dimension models have new resonances which could contribute to Drell-Yan
μ+
μ-
G
⇒ need to understand the SM contribution to high precision!
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where X=W, Z, H, high-ET jets, SUSY sparticles, black hole, …, and Q is the ‘hard scale’ (e.g. = MX), usually μF = μR = Q, and σ is known …
• to some fixed order in pQCD, e.g. high-ET jets
• or in some leading logarithm approximation (LL, NLL, …) to all orders via resummation
Summary: the QCD factorization theorem for hard-scattering (short-distance) inclusive processes
^
σ̂
• where ab→cd represents all quark & gluon 2→2 scattering processes
• NLO pQCD corrections also known
High-ET jet production
jet
jet
see QCD book
CDF
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jets at NNLOThe NNLO coefficient C is not yet known, the curves show guesses C=0 (solid), C=±B2/A(dashed) → the scale dependence and hence δ σthis significantly reduced
Other advantages of NNLO:
• better matching of partons ⇔hadrons• reduced power corrections• better description of final state kinematics (e.g. transverse momentum)
Glover
Tevatron jet inclusive cross section at ET = 100 GeV
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jets at NNLO contd.• 2 loop, 2 parton final state
• | 1 loop |2, 2 parton final state
• 1 loop, 3 parton final states or 2 +1 final state
• tree, 4 parton final states or 3 + 1 parton final states or 2 + 2 parton final state
⇒ rapid progress in recent years [many authors]
• many 2→2 scattering processes with up to one off-shell leg now calculated at two loops• … to be combined with the tree-level 2→4, the one-loop 2→3 and the self-interference of the one-loop 2→2 to yield physical NNLO cross sections• complete results expected ‘soon’
soft, collinear
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Higgs production
• the HO pQCD corrections to σ(gg→H) are large (more diagrams, more colour)
Ht
g
g
Djouadi & Ferrag
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top quark production
NLO known, but awaits full NNLO pQCD calculation; NNLO & NnLL“soft+virtual” approximations exist
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parton luminosity functions• a quick and easy way to assess the mass and collider energy dependence of production cross sections
s Ma
b
• i.e. all the mass and energy dependence is contained in the X-independent parton luminosity function in [ ]• useful combinations are • and also useful for assessing the uncertainty on cross sections due to uncertainties in the pdfs (see later)
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Tevatron
LHC
LHC / Tevatron
see CHS for more
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future hadron colliders: energy vs luminosity?
102 103 10410-1
100
101
102
103
104
105
106
107
108
14 TeV
40 TeV
parton luminosity: gg → X
gluo
n-gl
uon
lum
inos
ity
[pb]
MX [GeV]for MX > O(1 TeV), energy × 3 is better than luminosity × 10 (everything else assumed equal!)
recall parton-parton luminosity:
so that
with τ = MX2/s
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what limits the precision of the predictions?
• the order of the perturbative expansion
• the uncertainty in the input parton distribution functions
• example: σ(Z) @ LHCδσpdf ≈ ±3%, δσpt ≈ ± 2%→ δσtheory ≈ ± 4%
whereas for gg→H :δσpdf << δσpt
14
15
16
17
18
19
20
21
22
23
24
partons: MRST2002NNLO evolution: van Neerven, Vogt approximation to Vermaseren et al. momentsNNLO W,Z corrections: van Neerven et al. with Harlander, Kilgore corrections
NLONNLO
LO
LHC Z(x10)
W
σ . B
l (n
b)
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
3.2
3.4
3.6
NNLONLO
LO
Tevatron (Run 2)
CDF D0(e) D0(μ)
Z(x10)
W
CDF D0(e) D0(μ)
σ . B
l (
nb)
±4% total error(MRST 2002)
±2% total error(MRST 2002)
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pdf uncertainties• MRST, CTEQ, Alekhin, … also produce ‘pdfs
with errors’• typically, 30-40 ‘error’ sets based on a ‘best fit’
set to reflect ±1σ variation of all the parameters {Ai,ai,…,αS} inherent in the fit
• these reflect the uncertainties on the data used in the global fit (e.g. δF2 ≈ ±3% → δu ≈ ±3%)
• however, there are also systematic pdf uncertainties reflecting theoretical assumptions/prejudices in the way the global fit is set up and performed
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uncertainty in gluon distribution (CTEQ)
CTEQ6.1E: 1 + 40 error setsMRST2001E: 1 + 30 error sets
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high-x gluon from high ET jets data
• both MRST and CTEQ use Tevatron jets data to determine the gluon pdf at large x
• the errors on the gluon therefore reflect the measured cross section uncertainties
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why do ‘best fit’ pdfs and errors differ?• different data sets in fit
– different subselection of data– different treatment of exp. sys. errors
• different choice of– tolerance to define ± δ fi
(MRST: Δχ2=50, CTEQ: Δχ2=100, Alekhin: Δχ2=1)– factorisation/renormalisation scheme/scale – Q0
2
– parametric form Axa(1-x)b[..] etc– αS– treatment of heavy flavours– theoretical assumptions about x→0,1 behaviour– theoretical assumptions about sea flavour symmetry– evolution and cross section codes (removable differences!)
LHC σNLO(W) (nb)
MRST2002 204 ± 4 (expt)CTEQ6 205 ± 8 (expt)Alekhin02 215 ± 6 (tot)
similar partons different Δχ2
different partons
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Djouadi & Ferrag, hep-ph/0310209
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Note: CTEQ gluon ‘more or less’ consistent with MRST gluon
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• MRST: Q02 = 1 GeV2, Qcut
2 = 2 GeV2
xg = Axa(1–x)b(1+Cx0.5+Dx)– Exc(1-x)d
• CTEQ6: Q02 = 1.69 GeV2,
Qcut2 = 4 GeV2
xg = Axa(1–x)becx(1+Cx)d
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0.01 0.1 1-4-3-2-1012345678
f(x)
x0.01 0.1 1
-4-3-2-1012345678
f(x)
x0.01 0.1 1
-4-3-2-1012345678
f(x)
x
extrapolation errors
theoretical insight/guess: f ~ A x as x → 0
theoretical insight/guess: f ~ ± A x–0.5 as x → 0
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χ2
θ0 1 2 3 4 5 6 7 8 9 10 11 12 13 14
0.00
0.25
0.50
0.75
1.00
1.25
1.50
1.75
2.00
Experiment B
Experiment A
systematic error
systematic error
θ
measurement #
• with dataset A in fit, Δχ2=1 ; with A and B in fit, Δχ2=?
• ‘tensions’ between data sets arise, for example,– between DIS data sets (e.g. μH and νN data) – when jet and Drell-Yan data are combined with DIS data
tensions within the global fit
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CTEQ αS(MZ) values from global analysis with Δχ2 = 1, 100
beyond perturbation theorynon-perturbative effects arise in many different ways• emission of gluons with kT < Q0 off ‘active’ partons • soft exchanges between partons of the same or different beam
particlesmanifestations include…• hard scattering occurs at net non-zero transverse momentum• ‘underlying event’ additional hadronic energy
precision phenomenology requires a quantitative understanding of these effects!
‘intrinsic’ transverse momentumsimple parton model assumes partons have zero transverse momentum
… but data shows that the DY lepton pair is produced with non-zero <pT>
+
the perturbative tail is even more apparent in W, Z production at the Tevatron, and can be well accounted for by the 2→2 scattering processes:
… with known NLO pQCD corrections. Note that the pT distribution diverges as pT→0 due to soft gluon emission:
the O(αS) virtual gluon correction contributes at pT=0, in such a way as to make the integrated distribution finite
intrinsic kT can also be included, by convoluting with the pQCD contribution
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• when pT << M , the pQCD series contains large logarithms ln(M2/pT2)
at each order:
resummation
which spoils the convergence of the series when
• fortunately, these logarithms can be resummed to all orders in pQCD, to generate a Sudakov form factor:
… which regulates the LO singularity at pT = 0
• the effect of the form factor is (just about) visible in the (Tevatron) data
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resummation contd.
• theoretical refinements include the addition of sub-leading logarithms (e.g. NNLL) and nonperturbativecontributions, and merging the resummed contributions with the fixed order (e.g. NLO) contributions appropriate for large pT
• the resummation formalism is also valid for Higgs production at LHC via gg→H
qT (GeV)
KuleszaStermanVogelsang
Z
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• comparison of resummed / fixed-order calculations for Higgs (MH= 125 GeV) pT distribution at LHC
Balazs et al, hep-ph/0403052
• differences due mainly to different NnLO and NnLL contributions included
• Tevatron dσ(Z)/dpTprovides good test of calculations
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full event simulation at hadron colliders• it is important (designing detectors,
interpreting events, etc.) to have a good understanding of all features of the collisions – not just the ‘hard scattering’ part
• this is very difficult because our understanding of the non-perturbative part of QCD is still quite primitive
• at present, therefore, we have to resort to models (PYTHIA, HERWIG, …) …
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Monte Carlo Event Generators• programs that simulates particle physics events with the
same probability as they occur in nature• widely used for signal and background estimates• the main programs in current use are PYTHIA and HERWIG• the simulation comprises different phases:
– start by simulating a hard scattering process – the fundamental interaction (usually a 2→2 process but could be more complicated for particular signal/background processes)
– this is followed by the simulation of (soft and collinear) QCD radiation using a parton shower algorithm
– non-perturbative models are then used to simulate the hadronizationof the quarks and gluons into the observed hadrons and the underlying event
a Monte Carlo event
t
t̄
q
q̄
Initial and Final State parton showers resum the large QCD logs.
Hard Perturbative scattering:
Usually calculated at leading order in QCD, electroweak theory or some BSM model.
Perturbative Decays calculated in QCD, EW or some BSM theory.
Multiple perturbative scattering.
Non-perturbative modelling of the hadronization process.
Modelling of the soft underlying event
Finally the unstable hadrons are decayed.
t
t̄
p, p̄
p, p̄
t
t̄ b̄
W−
b
W+
ν� �+
p, p̄
p, p̄
t
t̄ b̄
W−
b
W+
ν� �+
Hadrons
Hadr
ons
Hadron
s
Hadr
ons
Hadr
ons
Hadrons
Hadr
ons
p, p̄
p, p̄
t
t̄ b̄
W−
b
W+
ν� �+
Hadrons
Hadr
ons
Hadron
s
Hadr
ons
Hadr
ons
Hadrons
Hadr
ons
Hadr
ons
p, p̄
p, p̄
t
t̄ b̄
W−
b
W+
ν� �+
p, p̄
p, p̄
from Peter Richardson (HERWIG)
(had
ron
colli
der)
pro
cess
es in
HE
RW
IG
from
Pet
er R
icha
rdso
n
SS
I 200
678
how
ever
…•
the
tuni
ng o
f the
non
pertu
rbat
ive
parts
of t
he m
odel
s is
pe
rform
ed a
sin
gle
colli
der e
nerg
y (o
r lim
ited
rang
e of
en
ergi
es) –
can
we
trust
the
extra
pola
tion
to L
HC
?!
•in
gen
eral
the
even
t gen
erat
ors
only
use
lead
ing
orde
r m
atrix
ele
men
ts a
nd th
eref
ore
the
norm
alis
atio
n is
un
certa
in•
this
can
be
over
com
e by
reno
rmal
isin
gto
kno
wn
NLO
et
c re
sults
or b
y in
corp
orat
ing
next
-to-le
adin
g or
der
mat
rix e
lem
ents
(rea
l + v
irtua
l em
issi
ons)
–se
e be
low
•on
ly s
oft a
nd c
ollin
ear e
mis
sion
is a
ccou
nted
for i
n th
e pa
rton
show
er, t
here
fore
the
emis
sion
of a
dditi
onal
har
d,
high
ET
jets
is g
ener
ally
sig
nific
antly
und
eres
timat
ed•
for t
his
reas
on, i
t is
poss
ible
that
man
y of
the
prev
ious
LH
C s
tudi
es o
f new
phy
sics
sig
nals
hav
e si
gnifi
cant
ly
unde
rest
imat
ed th
e S
tand
ard
Mod
el b
ackg
roun
ds
tt̄
p,p̄
p,p̄
+
inte
rfaci
ng N
n LO
and
parto
n sh
ower
s
Ben
efits
of b
oth:
Nn L
Oco
rrect
ove
rall
rate
, har
d sc
atte
ring
kine
mat
ics,
redu
ced
scal
e de
p.PS
com
plet
e ev
ent p
ictu
re, c
orre
ct tr
eatm
ent o
f col
linea
r log
s to
all
orde
rs
Exam
ple:
MC
@N
LO
Frix
ione
, Web
ber,
Nas
on,
ww
w.h
ep.p
hy.c
am.a
c.uk
/theo
ry/w
ebbe
r/MC
atN
LO/
proc
esse
s in
clud
ed s
o fa
r …pp
→W
W,W
Z,ZZ
,bb,
tt,H
0 ,W,Z
/γ
p Tdi
strib
utio
n of
ttat
Tev
atro
n
SS
I 200
681
and
final
ly …
SS
I 200
682
cent
ral e
xclu
sive
diff
ract
ive
phys
ics
•p +
p →
H +
X–
the
rate
(σpa
rton,
pdfs
, αS)
–th
e ki
nem
atic
dist
ribtn
s. (d
σ/dy
dpT)
–th
e en
viro
nmen
t (je
ts, u
nder
lyin
g ev
ent,
back
grou
nds,
…)
μ μ
μ μ
•p +
p →
p +
H +
p–
a re
al c
halle
nge
for t
heor
y (p
QC
D+
npQ
CD
) and
exp
erim
ent
(tagg
ing
forw
ard
prot
ons,
tri
gger
ing,
…)
com
pare
…
with
…
b
b
SS
I 200
683
EM
E
IC
D/M
G E
FH
E
CH
E
hard
dou
ble
pom
eron
hard
col
or
sing
let e
xcha
nge
‘rapi
dity
gap
’col
lisio
n ev
ents
DDty
pica
l jet
eve
nt
hard
sin
gle
diffr
actio
n
forw
ard
prot
on ta
ggin
g at
LH
C: t
he p
hysi
cs c
ase
•al
l obj
ects
pro
duce
d th
is w
ay m
ust b
e in
a 0
++st
ate →
spin
-par
ity
filte
r/ana
lyse
r•
with
a m
ass
reso
lutio
n of
~O
(1 G
eV) f
rom
the
prot
on ta
ggin
g, th
e S
tand
ard
Mod
elH
→bb
deca
y m
ode
open
s up
, with
S/B
> 1
•H
→W
W( *)
also
look
s ve
ry p
rom
isin
g
•in
cer
tain
regi
ons
of M
SS
Mpa
ram
eter
sp
ace,
S/B
> 2
0, a
nd d
oubl
e pr
oton
tagg
ing
is T
HE
disc
over
y ch
anne
l
•in
oth
er re
gion
s of
MS
SM
par
amet
er s
pace
, exp
licit
CP
vio
latio
n in
th
e H
iggs
sec
tor s
how
s up
as
an a
zim
utha
lasy
mm
etry
in th
e ta
gged
pr
oton
s →
dire
ct p
robe
of C
P s
truct
ure
of H
iggs
sec
tor a
t LH
C•
any
exot
ic 0
++st
ate,
whi
ch c
oupl
es s
trong
ly to
glu
e, is
a re
al
poss
ibili
ty: r
adio
ns, g
luin
obal
ls, …
p +
p →
p ⊕
X ⊕
p
e.g.
mA
= 13
0 G
eV,
tan
β=
50ΔM
= 1
GeV
, L =
30
fb-1 S
B
mh
= 12
4.4
GeV
71
3
m
H=
135.
5 G
eV
124
2m
A=
130
G
eV
1
2
e.g.
SM
Hig
gs →
bbΔM
= 1
GeV
, L =
30
fb-1 S
B
mh
= 12
0 G
eV
11
4
Kho
ze M
artin
Rys
kin
SS
I 200
685
the
chal
leng
es …
gap survivalne
ed to
cal
cula
tepr
oduc
tion
ampl
itude
and
gap
Sur
viva
l Fac
tor:
mix
of p
QC
Dan
d np
QC
D⇒
sign
ifica
nt u
ncer
tain
ties
Khoz
eM
artin
Rys
kin
Kaid
alov
WJS
de R
oeck
Cox
Fors
haw
Mon
kPi
lkin
gton
Hel
sink
i gr
oup
Sacl
aygr
oup
…
theo
ry
expe
rimen
t
X
man
y! (f
orw
ard
prot
on/a
ntip
roto
n ta
ggin
g,
pile
-up,
low
eve
nt ra
te, t
rigge
ring,
…)
impo
rtant
che
cks
from
Tev
atro
n fo
r X=
dije
ts, γ
γ, q
uark
onia
, …
SS
I 200
686
sum
mar
y•
than
ks to
> 3
0 ye
ars
theo
retic
al s
tudi
es, s
uppo
rted
by
expe
rimen
tal m
easu
rem
ents
, we
now
kno
w h
ow to
cal
cula
te
(an
impo
rtant
cla
ss o
f) pr
oton
-pro
ton
collid
er e
vent
rate
s re
liabl
y an
d w
ith a
hig
h pr
ecis
ion
•th
e ke
y in
gred
ient
s ar
e th
e fa
ctor
isat
ion
theo
rem
and
the
univ
ersa
l par
ton
dist
ribut
ion
func
tions
•su
ch c
alcu
latio
ns u
nder
pin
sear
ches
(at t
he T
evat
ron
and
the
LHC
) for
Hig
gs, S
US
Y, e
tc
•…
but m
uch
wor
k st
ill n
eeds
to b
e do
ne, i
n pa
rticu
lar
–ca
lcul
atin
g m
ore
and
mor
e N
NLO
pQ
CD
corr
ectio
ns (a
nd s
ome
mis
sing
NLO
one
s to
o) –
see
Lanc
e D
ixon
’s le
ctur
es–
furth
er re
finin
g th
e pd
fs, a
nd u
nder
stan
ding
thei
r unc
erta
intie
s–
unde
rsta
ndin
g th
e de
taile
d ev
ent s
truct
ure,
whi
ch is
out
side
the
dom
ain
of p
QC
Dan
d is
cur
rent
ly s
impl
y m
odel
led
–ex
tend
ing
the
calc
ulat
ions
to n
ew ty
pes
of N
ew P
hysi
cs
prod
uctio
n pr
oces
ses,
e.g
. exc
lusi
ve/d
iffra
ctiv
e pr
oduc
tion
