dipole model & the daf-pomeron @ hera, lhc, eic, lhec...low-x physics @ hera f (x,q ) q 4 π...
TRANSCRIPT
![Page 1: Dipole Model & the DAF-Pomeron @ HERA, LHC, EIC, LHeC...Low-x Physics @ HERA F (x,Q ) Q 4 π ασ (W,Q ) 2 2 2 em 2 γ P 2 tot * = ⋅ ≈ < 0.01 2 2 W Q x ImA (W ) W 1 σ 2 2 el γp](https://reader035.vdocuments.mx/reader035/viewer/2022071511/6130f20a1ecc515869446bc4/html5/thumbnails/1.jpg)
Dipole Model & the DAF-Pomeron@ HERA,
LHC, EIC, LHeC
Henri Kowalski
Trento, ECT*15th of July 2008
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Ongoing InvestigationFirst talks at Columbia & Hampton Universities, May 2008
hep-ph/0803.0258
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Outline of the talk:
Short review of low x HERA data, Dipole Picture,Saturation, oomph factor and all that
Why Pomeron at HERA?,
What is DAF-BFKL PomeronEvidence for DAF-Pomeron from HERA data
Relation with DGLAP MRST EKR
Pomeron-Graviton Correspondence
Consequences for RHIC, LHC, EIC, LHeC
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• At low x and high Q2, steep rise in structure function
Low-x Physics @ HERA
Behavior of F2 is dominatedby gluon density at small-x
p
e
e
γ* Parton Picture
BFKL orDipolePicture
F2
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Low-x Physics @ HERA
)Q(x,FQα π4 )Q(W,σ 2
2 2em
22Pγ
tot
*
⋅=
01.0 <≈ 2
2
WQx
)(WImAW
1σ 2el2
pγtot
*
=
Diffraction at HERA is a shadow of DIS
dipole picture,equivalent to LO p-QCD for smalldipoles, Q~1/r
NNPZ, AM, GLM, FKS, GBWDGKP, BGBK, IIM, FSS……KT - Kowalski, TeaneyKMW - K, Motyka, WattKLMV – K, Lappi, Marquet, Venugopalan
KLMV
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Dipole Picture-gluon density convoluted with the dipole wave functions simultaneous prediction/description of many reactions
KMW Vector Mesons
DVCS
Note: educated guesses for VM wf work very well
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F2
c
IP Sat-Mod, mc= 1.3 GeV ZEUS
x
x
0
0.2
0.4
0
0.2
0.4
10-4
10-3
10-2
0
0.2
0.4
10-4
10-3
10-2
10-4
10-3
10-2
F2 C
KT
Diffractive Di-jets Q2 > 5 GeV2
Dipole Picture-gluon density convoluted with the dipole wave functions simultaneous prediction/description of many reactions
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K+Watt
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2*VM
1
0
Δbi22pγ
VM |Ψ)2Ωexp(12Ψdzebdrd|
16π1
dtdσ
*
⎭⎬⎫
⎩⎨⎧ −−= ∫∫∫ ⋅−
rrr
)2/exp(~)(
)exp(~
2 BbbT
tBdt
d diff
r−⇒
⋅σ
T(b)-proton shape)T(b)μ)xg(x,(μαrNπΩ 22
s2
C
2
=
Extracting Proton Vertex using Dipole Models
),( zrΨ
KT, KMW
Can use vector meson production to extract proton profile:
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How Important is Saturation?
• Eikonal exponentiation (Glauber-Mueller, MV):
• Depends on impact parameter, momentum scale• Define saturation scale Qs by
• Estimate Qs using indicative models for proton impact-parameter profile and gluon distribution:
• + DGLAP evol.
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Estimate of Qs
How Important is Saturation?
Apparently little saturation at
Qs2 = 4 GeV2
Oomph factor Increase
saturation by going to nuclei
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Low-x Physics @ HERA
• Increasing rate of growthwith Q2, well described by DGLAP evolution
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Discovery of HERA
Universality of the observed intercepts
Universal, “Pomeron like” QCD objectsoft and hard Pomeron join together
universal rate of rise of all hadronic cross-sections
tottot* λλ2pγ (1/x)~)(W~σ
exclusivediffractive ρ
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Basics of BFKL
BFKL equation at q=0
Eigen-functions
Characteristic function
BFKL
BFKL
solved by finding a complete setof eigenfunctions
Conformal invariance
χ(ν) = −2γΕ −ψ(1/2 + iν) −ψ(1/2 – iν)ψ is the Digamma function
Greenfunction
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NLO BFKL with running αS
running coupling
NLO
property of χ:largest ω at ν=0
Airy functions are solving BFKL eq. around k~kcrit
Fadin, LipatovG. Salamresummation
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Matching the solutions at k=kcrit determines the phase of oscil.= π/4Lipatov 86 encode the infrared behaviour of QCD by
assuming a fixed phase η at k0
away of kcrit
η = −0.16π
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unintegrated gluon densityBFKL
Structure functions in DIS
ΦDIS known in QCD
ΦDIS
ΦP
ΦP barely known
enhancement of leading eigenfun.by (1/x)ω
no enhancement of leading eigenfun.
HERALHeC
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Kwiecinski, MartinStasto
ΦDIS
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Fit with charm
Correct qualitative behaviour from leading singularity
Excellent fit to data for x < 10-2 with 3, 4 poles
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Contributions to F2 of the individual eigenfunctions
good data descriptiondue to interferences
phase η preciselydetermined
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Sum of contributionswith small eigenvaluescan give a largerrate of rise than the leading eigenvalue !!!
λλ2pγ (1/x)~)(W~σ*
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Where Do BFKL and DGLAP Meet
Unintegrated BFKL gluon density (LO, no running αS)
Saddle point
equal to DLL limit of DGLAP (LO, no running αS)
valid if
γ = ½ +iν
Lipatov, private communication
! not fulfilled for HERA or even Higgs at LHC !
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⎭⎬⎫
⎟⎠
⎞⎜⎝
⎛+
⎩⎨⎧
⎟⎠
⎞⎜⎝
⎛+
⎭⎬⎫
⎟⎠
⎞⎜⎝
⎛+
⎩⎨⎧
⎟⎠
⎞⎜⎝
⎛+= ∫∫ ξ
xCκμln
ξxP)(g
ξdξ
2πα
ξxC
κμln
ξxP)(q
ξdξ
2πα(x)q )μq(x, g2
2
qg0
1
x
Sq2
2
qq0
1
x
S0
2 ξξ
The QCD improved parton modelMRST/CTEQ approach
⎭⎬⎫
+⎟⎠
⎞⎜⎝
⎛⎩⎨⎧+
⎭⎬⎫
+⎟⎠
⎞⎜⎝
⎛+
⎩⎨⎧
−= ∫∑∫∑ ..., 2
ξxC
2)g(
ξdξex ...
ξxC
2πα)
ξxδ(1)Q,q(
ξdξex )Q(x,F MS
gS
1
xq
2q
MSq
S21
xq
2q
22 π
αξξ Q
second term gives avery small contribution
sea quark densities (input: q0(x) for every quark species..)
MS-bar scheme
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p
e
e
γ*)2
q
2q
22 Qq(x,ex )Q(x,F ∑=
k)k)xg(x,(Q,Φk
dkQ)q(x,Q
0DIS∫= .../lnd
1
x
+⎩⎨⎧
⎟⎠
⎞⎜⎝
⎛+= ∫ κμξ
ξξ
παμ
ξxP)(q(x)q )q(x, qq0
S0
2
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String theory emerged out of phenomenology of hadron-hadron scattering
Dolan-Horn-Schmid duality between s-channel and t-channel Regge-pole descriptionof hadronic X-sections
Veneziano amplitude
generalization by Virasoro dual models
mesons are open strings, closed strings necessary for unitarity
Virasoro-amplitude for =1 has a pole at s = t = 0with J = 2, a graviton starting point for theory of quantum gravity
Superstring Theory, Green, Schwarz, Witten (1987) R. Brower hep-th/0508036
Pomeron-Graviton Correspondence
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Maldacena Conjecturefrom the talk by J. Maldacena
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Pomeron and Gauge/String DualityBrower, Polchinski, Strassler, and Tan, hep-th/0603115
Pomeron is a coherent color-singlet object, build from gluons, with universal properties; it is a closed string propagating in ADS space,when the conformal symmetry is broken at some infrared point in the fifth dimension
in ADS/CFT
in N=4 YM SuSy QCDKotikov, Lipatov, Onishchenko, Velizhanin, Physt. Lett. B 632, 754 (2006)
LO – BFKL
BPST ω
N4π22ω1
Sα−=+
ω =0.27
BFKL at fixed weak couplingbare graviton at fixed strong coupling
Stasto, hep-ph/0702195QCD resummation
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Consequences for LHC
Good knowledge of gluon density around x~10-2 and Q2~10000 GeV2
is essential for LHC physics (Higgs region)
Large effort is going into precise measurement of W and Z inclusive X-sections precise determination of sea-quark distributions
precise gluon density
Is the sea-quark gluon density relation the same in the DGLAP-like picture (MRST/CTEQ) and DAF-Pomeron?
sea-quark gluon relation can be checked by the jets with pT around 50 GeV?
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Consequences for LHC
Can be measured with help of forward detectors down to x~10-7 ?
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Consequences for LHC
– Examples:• pp → p (jet pair), pp → p (D Λc)• pp → p ηc p, (RHIC) pp → p H p (LHC)• pp → p (jet pair) p
Measure the t-dependence of ω:Is DAF-Pomeron moving towards the Graviton or away from it? (EIC)
• Consider diffractive production of a ‘small’ object• Single or double diffraction?
– y = ln(s/mX2) or y1 + y2 = ln(s/mX
2) ?
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Consequences for EIC
Measure precisely the dependence of inclusive and exclusive diffractive processes (DVCS, J/Psi, rho, phi…)
Investigate QCD evolution with diffractive processespure evolution of ~(gluon density)2t-dependence of effective exponents
!!! Investigate Structure of Matter as x increases !!!
Note: QCD evolution at HERA studied only with F2H1 and ZEUS measurement for F2 agree to ~3%for diffractive processes systematic differencesare factor 10 larger
Main reason: HERA experiments control only ~2/3of the rapidity range
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Instead of Conclusions
Study of Gluon Density are very important becauseit is the analog of Black Body Radiation in QED
It seemed hopeless to study pure Gluon Radiation since it is never free. However, it is becoming free for a short moment in HEP reactions
HERA has shown that physics processes at low-x are completely dominated by pure Gluon Density,
Investigation of Gluon Density has a chance to become asfundamental as Black Body radiation
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NLO BFKL with running αS
Matching the solutions at k=kcrit determines the phase of oscilations = π/4
Lipatov 86 encode the infrared behaviour of QCD byassuming a fixed phase η at k0
for all regions:
Quantization condition
solution away from kcrit
near k~k0
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⎭⎬⎫
⎟⎠
⎞⎜⎝
⎛+
⎩⎨⎧
⎟⎠
⎞⎜⎝
⎛+
⎭⎬⎫
⎟⎠
⎞⎜⎝
⎛+
⎩⎨⎧
⎟⎠
⎞⎜⎝
⎛+= ∫∫ ξ
xCκμln
ξxP)(g
ξdξ
2πα
ξxC
κμln
ξxP)(q
ξdξ
2πα(x)q )μq(x, g2
2
qg0
1
x
Sq2
2
qq0
1
x
S0
2 ξξ
The QCD improved parton modelMRST/CTEQ approach
⎭⎬⎫
+⎟⎠
⎞⎜⎝
⎛⎩⎨⎧+
⎭⎬⎫
+⎟⎠
⎞⎜⎝
⎛+
⎩⎨⎧
−= ∫∑∫∑ ..., 2
ξxC
2)g(
ξdξex ...
ξxC
2πα)
ξxδ(1)Q,q(
ξdξex )Q(x,F MS
gS
1
xq
2q
MSq
S21
xq
2q
22 π
αξξ Q
second term gives avery small contribution
sea quark densities
MS-bar scheme
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Consequences for EIC
Measure precisely the dependence of inclusive and exclusive diffractive processes (DVCS, J/Psi, rho, phi…)
Investigate QCD evolution with diffractive processespure evolution of (gluon density)2t-dependence of effective exponents!
Note: QCD evolution at HERA studied only with F2H1 and ZEUS measurement for F agree to ~3%for diffractive processes systematic diffrencesare factor 10 larger
Main reason: HERA experiments control only ~2/3of the rapidity range
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measurement of α’
)(1)(
tnctJn δ+
+=
Significant slope is expected for a leading pomeron trajectoryLipatov (1986)
NgR YM/2=′αBPST