EVMP: Nucleons vs. Nuclei An Update

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Presentation transcript:

EVMP: Nucleons vs. Nuclei An Update W. A. Horowitz University of Cape Town February 2, 2012 11/29/2018 CPTEIC

Motivation Many-body QCD: Quantitative extraction of properties (h/s, E-loss,...) requires quantitative knowledge of the geometry Physics of “the edge” very important, not under good theoretical control (non-perturbative) EVMP provides an independent, direct measurement of the small-x nuclear profile Very sensitive to edge physics 11/29/2018 CPTEIC

Motivating EVMP Recall e + A exps. on A at rest Invert Dirac => Woods-Saxon distribution! Hahn, Ravenhall, and Hofstadter, Phys Rev 101 (1956) 11/29/2018 CPTEIC

Gluon Distribution of A e J/y A g* Coherent vector meson production in e + A Invert ds/dt to measure gluon distribution See diff. in ds/dt from diff. gluon evolution? 11/29/2018 CPTEIC

ds/d2b: DGLAP First Work: Compare DGLAP and KLN 2-gluon exchange straw men 1) Assume incoherent interaction with nucleons (a la Caldwell & Kowalksi) & DGLAP T: glue distribution in nucleon: Integrate over WS distribution of nucleons in nucleus 11/29/2018 CPTEIC

ds/d2b: KLN 2) small-x evo. approx. by KLN xgA is integrated KLN UGD: coherent nuclear effect Simple KLN form for UGD Back of the envelope calc. of Qs 11/29/2018 CPTEIC

EVMP ds/dt Result Huge growth in DGLAP Glauber x-scn WAH, arXiv:1102.5058 Must reject incoherent collisions at ~100% Huge growth in DGLAP Glauber x-scn Nuclear shape changes for KLN, not for DGLAP Glauber 11/29/2018 CPTEIC

Two Issues 1) Only 2 gluon exchange Expect mult. int. at saturation Both straw men can violate black-disc limit 2) Pathology in nuclear size for KLN b (fm) ds/d2b DGLAP Glauber (Blue) KLN CGC (Black) IPSat (Red) r = 1 GeV-1 x = 10-3 11/29/2018 CPTEIC

First, Unitarize Cut off DGLAP dipole at 1 Exponentiate KLN ds/d2b r = 1 GeV-1 x = 10-6 ds/d2b DGLAP Glauber (Blue) KLN CGC (Black) IPSat (Red) b (fm) 11/29/2018 CPTEIC

Unitarized Results DGLAPU (B, P, G; solid) DGLAP (B, P, G; dashed) DGLAPU (B, P, G) KLNU (Teal Band) x = 10-3 x = 10-6 ds/dt ds/dt t (GeV2) t (GeV2) Sig. shape diff. from unitarization. NB esp. changes due to MSTW uncertainties, KLN’s slower dropoff Little Change at “large” x 11/29/2018 CPTEIC

Conclusions & Future Work 10-6 Results tantalizing proof of principle See effect of coherence, saturation Large effects from unconstrained PDF Future Work ds/dt directly from ds/d2b = 2N from rcBK Comparison over range in x, including “large” x Smaller PDF uncertainties Explicitly see evolution of nuclear size with x 11/29/2018 CPTEIC

11/29/2018 CPTEIC

ds/d2b Simple 2-gluon exchange Assume DGLAP evo. of glue & incoherent interaction with nucleons Assume small-x evo. approx. by KLN xgA is integrated KLN UGD, coherent nuclear effect 11/29/2018 CPTEIC

KLN Gluon Distribution Obtain GD from UGD Simple KLN form for UGD Back of the envelope Qs formula 11/29/2018 CPTEIC

Gluon Distribution of A at x ~ 10-3 e J/y A g* Coherent vector meson production in e + A Must reject incoherent collisions at ~100% WAH, arXiv:1102.5058 11/29/2018 CPTEIC

X-scn: 11/29/2018 CPTEIC

ds/d2b Simple 2-gluon exchange Assume DGLAP evo. of glue & incoherent interaction with nucleons Assume small-x evo. approx. by KLN xgA is integrated KLN UGD, coherent nuclear effect 11/29/2018 CPTEIC