Universal features of QCD dynamics in hadrons & nuclei at high energies

Universal features of QCD dynamics in hadrons & nuclei at high energies Raju Venugopalan DNP (APS/JPS) meeting, Hawaii, October 13, 2009

High Energy QCD • QCD is the “nearly perfect” fundamental theory of the strong interactions(F.Wilczek, hep-ph/9907340) • We are only beginning to explore the high energy, many body dynamics of this theory What are the right effective degrees of freedom at high energies? -- gluons & sea quarks, dipoles, pomerons, strong fields? How do these degrees of freedom interact with each other and with hard probes? -- Multi-Pomeron interactions, Higher Twist effects, Saturation/CGC -- Rapidity Gaps, Energy loss, Multiple Scattering, Color Transparency -- Glasma, Quark Gluon Plasma What can this teach us about confinement, universal features of the theory (infrared fixed point?) -- hard vs soft Pomerons, Strong Fields, in-medium hadronization -

High Energy QCD-the role of Glue Localized energy fluctuation of Gluon Field (D. Leinweber) Self-interacting carriers of the strong force Dominate structure of QCD vacuum MILC Coll.: hep-lat/0304004 Hadron mass spectrum vs quenched lattice results full QCD Quenched QCD Nearly all visible matter in the universe is made of Glue

Measuring Glue: what are our options? Gluon jet event in e+e- collisions at LEP • p+A and e+A provide complementary information on role of glue • Need both to test what’s universal and what’s not in QCD processes • Some final states differ dramatically (diffractive/exclusive states) Nothing matches DIS for precision-vast majority of world data for pdfs (especially for glue) from DIS

Inclusive DIS Measure of resolution power Measure of inelasticity Measure of momentum fraction of struck quark quark+anti-quark mom. dists. gluon mom. dists

HERA data on inclusive DIS Gluon distribution from scaling violations of F2 Proton is almost entirely glue by x=0.01 for Q2 = 10 GeV2 Parton Density x= fraction of momentum of hadron carried by parton

HERA data on inclusive DIS # partons per unit rapidity For Q2 ≤ 5 GeV2, leading twist (“parton gas”) description problematic. Sign of higher twist (multi-parton correlation) effects? Recent HERA data on FL (H1: Q2 = 12-90 GeV2 ; ZEUS Q2 = 24-110 GeV2) EIC can add significantly to world FL data set -- even for protons. Important test of QCD evolution Golec-Biernat, Stasto, arXiv: 0905.1321

Resolving the hadron in the Bjorken limit of QCD -DGLAP evolution increasing Q2 But… the phase space density decreases-the proton becomes more dilute Important for precision/ beyond standard model physics

Resolving the hadron in the Regge-Gribov limit of QCD -BFKL evolution - Large x IMF picture: Gluon phase space grows - saturates at occupation # f = - Small x Rest frame picture: Scattering amplitude is unity…

Large x - bremsstrahlung linear evolution (DGLAP/BFKL) Small x -gluon recombination non-linear evolution (BK/JIMWLK) Mechanism of gluon saturation in QCD Gribov,Levin,Ryskin Mueller,Qiu p, A Saturation scale QS(x) - dynamical scale below which non-linear (“higher twist”) QCD dynamics is dominant

The Color Glass Condensate McLerran, RV Jalilian-Marian,Kovner,Weigert Iancu, Leonidov,McLerran In the saturation regime: Strongest fields in nature! • CGC: Classical effective theory of QCD describing • dynamical gluon fields + static color sources in non-linear regime • Novel renormalization group equations (JIMWLK/BK) • describe how the QCD dynamics changes with energy • A universal saturation scale QS arises naturally in the theory

Saturation scale grows with energy Y=ln(x0/x)0,1,3,9 unintegrated gluon dist. from NLL RG evolution QS(x) Bulk of high energy cross-sections: obey dynamics of novel non-linear QCD regime Can be computed systematically in weak coupling Exact analogy to physics of “pulled” travelling wave fronts in stat. mech. Munier,Peschanski

Evidence from HERA for geometrical scaling Golec-Biernat, Stasto,Kwiecinski   = Q2 / QS2 F2 D VM, DVCS V F2D Marquet, Schoeffel hep-ph/0606079 • Scaling seen for F2D and VM,DVCS for same QS as F2 Gelis et al., hep-ph/0610435 • Scaling confirmed by “Quality factor” analysis • Recent NLO BK analysis: Albacete, Kovchegov,hep-ph-0704.0612 Recent caveats: Avsar, Gustafson, hep-ph/0702087

q z * r 1-z q P Inclusive DIS in saturation models • = 0.3; x0 = 3* 10-4 Machado, hep-ph/0512264 Kowalski, Teaney

Saturation Models-excellent fits to HERA data Kowalski et al., hep-ph/0606272 Also see Forshaw et al. hep-ph/0608161

Inclusive diffraction MX “Pomeron” Rapidity Gap Big surprise at HERA:~ 15% of all events are hard diffractive (MX > 3 GeV) events • In rest frame: 50 TeV electron hits proton - in 1/7 events proton remains intact • Diffractive structure functions in DIS measure quark and gluon content of Pomeron Collins

Caveat: Saturation scale extracted from HERA data inconsistent with model assumptions ? Model assumes Typical sat. scale is rather low... QS2 << 1 GeV2

Saturation scale grows with A High energy compact (1/Q < Rp) probes interact coherently across nuclear size 2 RA - experience large field strengths c ~ 1 in saturation model fit to HERA extrapolated to nuclei Kowalski, Lappi, RV Enhancement of QS with A => non-linear QCD regime reached at significantly lower energy in A than in proton

Evidence of geometrical scaling in nuclear DIS Freund et al., hep-ph/0210139 Geometrical scaling Nuclear shadowing: • Data scale as a function of  = Q2 / QS2

600 1200 Krasnitz, RV Evidence of non-linear saturation regime @ RHIC ? Global multiplicity observables in AA described in CGC models: Input is QS(x,A) PHOBOS central Au+Au mult. vs models Kharzeev,Levin,Nardi

DA: Kharzeev,Kovchegov,Tuchin Albacete,Armesto,Salgado,Kovner,Wiedemann Blaizot, Gelis, RV D-Au pt spectra compared to CGC prediction Hayashigaki, Dumitru, Jalilian-Marian Forward pp @ RHIC as well Boer, Dumitru, PRD 74, 074018 (2006) Review: Jalilian-Marian, Kovchegov, hep-ph/0505052

Natural explanation for limiting fragmentation + deviations in CGC Jalilian-Marian Extrapolation of BK-fit to RHIC LF data to LHC dn/dy|_{y=0} = 1500-2250 in A+A at LHC Gelis,Stasto, RV, hep-ph/0605087

Terra Incognita Why Physics at an e+A collider is interesting Not your grand aunt’s e+A: world’s first such collider, first measurements of a range of final states… eg. rapidity gaps, jets, impact parameter dependent distributions • Large x and Q2 : Precision study of propagation of colored • probes in extended QCD medium. QCD showering and • fragmentation in nuclei • Small x: Explore physics of strong, non-linear color fields

What are the measurements? • Would like answers to: • What is the momentum distribution of gluons in matter • What is the space-time distribution of gluons in matter • How do fast probes interact with the gluonic medium? • What is the nature of color neutral exchanges (Pomerons) Tools/Measurements: • Precision inclusive measurements of structure functions : : (Inclusive diffraction) • Semi-inclusive measurements of final state distributions • Exclusive final states Multiple handles: x, Q2, t, MX2 for light and heavy nuclei

Gluon distribution from FL @ eRHIC Eskola,Paukkunen,Salgado EIC: 10 GeV + 100 GeV/n - estimate for 10 fb-1 Quark and Glue contribution to Hadron-hadron inclusive Cross-section

Inclusive diffraction • In pQCD, expect exponential suppression of large gaps • -- parametrize data with diffractive structure functions • which obey QCD evolution…not universal • In CGC, diffractive structure functions depend on universal dipole cross-section squared. Diffractive cross-section ~ 25% of total cross-section! Large  = small MX Small  = large MX Interesting pattern of enhancement and suppression-can be tested Kowalski,Lappi,Marquet,RV

Exclusive final states in DIS Brodsky et al. Frankfurt,Koepf,Strikman In the dipole model: Kowalski,Motyka,Watt Extract b dist. of glue In nuclei? Claim: can extract t dependence in photo-production of J/ down to t = 10-4 GeV2 Caldwell-Kowalski

Universal gluodynamics & energy dependence of QS A.H. Mueller, hep-ph/0301109 Small x QCD RG eqns. predict (fixed b) QS approaches universal behavior with increasing energy (Y) for all hadrons and nuclei -can the approach to this behavior be tested ?

In eA DIS, cleanly access cross-over region from weak field to novel strong field QCD dynamics ? Weak field regime Q2 >> QS2 Strong field regime Q2 << QS2 Qualitative change in final states: eg., 1/Q6 1/Q2 change in elastic vector meson production McDermott,Guzey,Frankfurt,Strikman; Review: Frankfurt, Strikman, Weiss

Semi-inclusive DIS Virtual photon with short coherence length scatters off quark or gluon (photon-gluon fusion) in medium - jet propagates through medium Vastly extended reach at EIC relative to HERMES, Jlab, EMC Precision studies of heavy quark energy loss Accardi,Dupre,Hafidi,

Glasma Initial Singularity sQGP - perfect fluid Color Glass Condensates Hadron Gas What does a heavy ion collision look like ? t

Before: transverse E & B “Weizsacker-Williams fields generate Chern-Simons topological charge parallel color E & B fields Lappi,McLerran,NPA 772 (2006) Kharzeev, Krasnitz, RV, Phys. Lett. B545 (2002) Glasma flux tubes from small x dynamics Krasnitz,Nara, RV; Lappi After: boost invariant Glasma flux tubes of size 1/QS

Au+Au 200 GeV, 0 - 30% PHOBOS preliminary Imagining the Glasma through long range rapidity correlations Causality dictates:  < 1 fm for y > 4 At LHC can probe color field dynamics for  << 1 fm… Very sensitive to gluon correlations in wave fn.

Lattice Gauge Theory Condensed Matter Physics High Energy Physics (LHC,LHeC Cosmic Rays) (B-E Condensates, Spin Glasses Graphene) Theory @ EIC

Inclusive Diffraction-II Impact parameter dipole (CGC) models give -sq. fits ~ 1 to HERA e+p inclusive and diffractive cross-section: H. Kowalski, C. Marquet, T. Lappi and R. Venugopalan, Phys. Rev. C 78, 045201 (2008). • = parton mom./Pomeron mom. xP= Pomeron mom./ Hadron mom.

Estimates of the saturation scale from RHIC A

Turbulent “thermalization” may lead to “anomalously” low viscosities Asakawa, Bass, Muller; Dumitru, Nara, Schenke, Strickland • Significant energy loss in Glasma because of synchroton like radiation? Shuryak, Zahed; Zakharov; Kharzeev The unstable Glasma Romatschke, RV:PRL 96 (2006) 062302 • Small rapidity dependent quantum fluctuations of the LO Yang-Mills fields grow rapidly as • E and B fields as large as EL and BL at time Possible mechanism for rapid isotropization Problem: collisions can’t ‘catch up’

NCS= -2 -1 0 1 2 + Topological fluctuations -sphaleron transitions in Glasma External (QED) magnetic field L or B STARPreliminary = Possible experimental signal of charge separation (Voloshin, Quark Matter 2009) Chiral magnetic effect P and CP violation: Chiral Magnetic Effect Kharzeev,McLerran,Warringa Effect most significant, for transitions at early times

Semi-inclusive DIS At small x: Hadron distributions and multiplicities sensitive to QS(x,A) Kang,Qiu Ratio to x = 10-2 proportional to ratio of QS2(x,A) Need more quantitative studies for EIC kinematics Marquet,Xiao,Yuan

Solution: for early times (t  1/QS) -- n-gluon production computed in A+A to all orders in pert. theory to leading log accuracy Gelis, Lappi, RV; arXiv : 0804.2630, 0807.1306, 0810.4829 Forming a Glasma in the little Bang Glasma (\Glahs-maa\):Noun:non-equilibrium matter betweenColor Glass Condensate (CGC)& Quark Gluon Plasma (QGP) • Problem: Compute particle production in QCD with strong time dependent sources

New window on universal properties of the matter in nuclear wavefunctions Iancu, RV, hep-ph/0303204 A Can we quantify the various regimes ?

Strong color fields may be more accessible in eA collisions relative to ep Nuclear profile more uniform-can study centrality dependence of distributions

Outline of talk • Whither the “perfect” theory ? - QCD at high energies • QCD coherence at small x => Universality - Saturation in hadrons & nuclei; the Color Glass Condensate picture • Exploring the structure of high energy nuclei with EIC - enteringterra incognita • From Glue to Glasma & QGP - how multi-parton correlations in nuclei generate extreme states of quark-gluon matter

Universal features of QCD dynamics in hadrons & nuclei at high energies