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Cronin Effect and High-p T Suppression in pA Collisions Yuri Kovchegov University of Washington Based on work done in collaboration with Based on work.

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Presentation on theme: "Cronin Effect and High-p T Suppression in pA Collisions Yuri Kovchegov University of Washington Based on work done in collaboration with Based on work."— Presentation transcript:

1 Cronin Effect and High-p T Suppression in pA Collisions Yuri Kovchegov University of Washington Based on work done in collaboration with Based on work done in collaboration with Dmitri Kharzeev and Kirill Tuchin, hep-ph/0307037

2 Gluon Production in pA: McLerran-Venugopalan model Classical gluon production: we need to resum only the multiple rescatterings of the gluon on nucleons. Here’s one of the graphs considered. Yu. K., A.H. Mueller, hep-ph/9802440 Resulting inclusive gluon production cross section is given by With the gluon-gluon dipole-nucleus forward scattering amplitude

3 McLerran-Venugopalan model: Cronin Effect Defining we can plot it for the quasi-classical cross section calculated before. One can actually do the integration analytically obtaining (Y.K., A. M. ‘98) Classical gluon production leads to Cronin effect! (see also B. Kopeliovich et al, ’02, R. Baier et al, ‘03)

4 Proof of Cronin Effect  Plotting a curve is not a proof of Cronin effect: one has to trust the plotting routine.  To prove that Cronin actually does take place one has to study the behavior of R pA at large k T (cf. Dumitru, Gelis, Jalilian-Marian, quark production, ’02-’03): R pA approaches 1 from above at high p T  there is an enhancement! Note the sign!

5 Cronin Effect Cronin Effect  The height and position of the Cronin maximum are increasing functions of centrality! The position of the Cronin maximum is given by k T ~ Q S ~ A 1/6 as Q S 2 ~ A 1/3. Using the formula above we see that the height of the Cronin peak is R pA (k T =Q S ) ~ ln Q S ~ ln A.

6 Including Quantum Evolution To understand the energy dependence of particle production in pA one needs to include quantum evolution resumming graphs like this one. This resums powers of  ln 1/x =  Y. This has been done in Yu. K., K. Tuchin, hep-ph/0111362. The rules accomplishing the inclusion of quantum corrections are where the dipole-nucleus amplitude N is to be found from (Yu. K., Balitsky) Proton’s LO wave function Proton’s BFKL wave function and 

7 Including Quantum Evolution In the traditional fan diagram language the calculated gluon production cross section is pictured above for DIS. Produced Gluon Can be proton or deuteron.

8 Including Quantum Evolution Amazingly enough, gluon production cross section reduces to k T –factorization expression: with the proton and nucleus “unintegrated distributions” defined by with N G p,A the amplitude of a GG dipole on a p or A.

9 Phase Diagram of High Energy QCD Moderate Energy or Rapidity Cronin effect and low-p T suppression QSQS High Energy or Rapidity QSQS k geom = Q S 2 /   p T 2 IIIIII

10 Region I: Double Logarithmic Approximation At very high momenta, p T >> k geom, the gluon production is given by the double logarithmic approximation, resumming powers of Resulting produced particle multiplicity scales as with where y=ln(1/x) is rapidity and Q S0 ~ A 1/6 is the saturation scale of McLerran-Venugopalan model. For pp collisions Q S0 is replaced by  leading to as Q S0 >>  R pA < 1 in Region I  There is suppression in DLA region!

11 The resulting gluon production cross section scales as Region II: Anomalous Dimension Kharzeev, Levin, McLerran, hep-ph/0210332 At somewhat lower but still large momenta, Q S < k T < k geom, the BFKL evolution introduces anomalous dimension for gluon distributions: such that For large enough nucleus R pA << 1 – high p T suppression!  How does energy dependence come into the game?  We are in the region with k T >> Q S >> Q S0. Shouldn’t R pA ~ k T / Q S0 be greater than 1 ? with BFKL  =1/2 (DLA  =1)

12 Region II: Anomalous Dimension R pA is also a decreasing function of energy, leveling off to a constant R pA ~ A -1/6 at very high energy.  R pA is a decreasing function of both energy and centrality at high energy / rapidity. (D. Kharzeev, Yu. K., K. Tuchin, hep-ph/0307037) A more detailed analysis gives the following ratio in the extended geometric scaling region – our region II:

13 Region III: What Happens to Cronin Peak? The position of Cronin peak is given by saturation scale Q S, such that the height of the peak is given by R pA (k T = Q S (y), y). It appears that to find out what happens to Cronin maximum we need to know the gluon distribution function of the nucleus at the saturation scale –  A (k T = Q S, y). For that we would have to solve nonlinear BK evolution equation – a very difficult task. Instead we can use the scaling property of the solution of BK equation which leads to Levin, Tuchin ’99 Iancu, Itakura, McLerran, ‘02  We do not need to know  A to determine how Cronin peak scales with energy and centrality! (The constant carries no dynamical information.)

14 Our Prediction Toy Model! Our analysis shows that as energy/rapidity increases the height of the Cronin peak decreases. Cronin maximum gets progressively lower and eventually disappears. Corresponding R pA levels off at roughly at D. Kharzeev, Yu. K., K. Tuchin, hep-ph/0307037; (see also numerical simulations by Albacete, Armesto, Kovner, Salgado, Wiedemann, hep-ph/0307179 and Baier, Kovner, Wiedemann hep-ph/0305265 v2.)  At high energy / rapidity R pA at the Cronin peak becomes a decreasing function of both energy and centrality. R pA k / Q S energy / rapidity increases

15 Overall Picture  At moderately high energy/rapidity one has to use McLerran-Venugopalan model to calculate gluon production. In McLerran-Venugopalan model one gets Cronin effect only. The height of the Cronin peak is an increasing function of centrality.  As energy/rapidity increases quantum effects due to BK evolution become important introducing high-p T suppression. Cronin peak gradually disappears. R pA becomes a decreasing function of energy and centrality.

16 Other Predictions Color Glass Condensate / Saturation physics predictions are in sharp contrast with other models. The prediction presented here uses a Glauber-like model for dipole amplitude with energy dependence in the exponent. figure from I. Vitev, nucl-th/0302002, see also a review by M. Gyulassy, I. Vitev, X.-N. Wang, B.-W. Zhang, nucl-th/0302077

17 Forward Rapidity Data BRAHMS collaboration preliminary data, presented by R. Debbe at DNP ‘03 Suppression!

18 It is very likely (pending final data) that Color Glass Condensate has just been discovered by dAu experiments at RHIC !

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