Anomalous centrality evolution of two-particle angular correlations from   Au-Au collisions at $\sqrt{s_{\rm NN}}$ = 62 and 200 GeV

STAR Collaboration: G. Agakishiev; M.M. Aggarwal; Z. Ahammed; A.V.; Alakhverdyants; I. Alekseev; J. Alford; B.D. Anderson; C.D. Anson; D.; Arkhipkin; G.S. Averichev; J. Balewski; D.R. Beavis; R. Bellwied; M.J.; Betancourt; R.R. Betts; A. Bhasin; A.K. Bhati; H. Bichsel; J. Bielcik; J.; Bielcikova; L.C. Bland; I.G. Bordyuzhin; W. Borowski; J. Bouchet; E. Braidot,; A.V. Brandin; S.G. Brovko; E. Bruna; S. Bueltmann; I. Bunzarov; T.P. Burton,; X.Z. Cai; H. Caines; M. Calderon; D. Cebra; R. Cendejas; M.C. Cervantes; P.; Chaloupka; S. Chattopadhyay; H.F. Chen; J.H. Chen; J.Y. Chen; L. Chen; J.; Cheng; M. Cherney; A. Chikanian; W. Christie; P. Chung; M.J.M. Codrington; R.; Corliss; J.G. Cramer; H.J. Crawford; X. Cui; A. Davila Leyva; L.C. De Silva,; R.R. Debbe; T.G. Dedovich; J. Deng; A.A. Derevschikov; R. Derradi de Souza,; L. Didenko; P. Djawotho; X. Dong; J.L. Drachenberg; J.E. Draper; C.M. Du,; J.C. Dunlop; L.G. Efimov; M. Elnimr; J. Engelage; G. Eppley; M. Estienne; L.; Eun; O. Evdokimov; R. Fatemi; J. Fedorisin; R.G. Fersch; P. Filip; E. Finch,; V. Fine; Y. Fisyak; C.A. Gagliardi; D.R. Gangadharan; F. Geurts; P. Ghosh,; Y.N. Gorbunov; A. Gordon; O.G. Grebenyuk; D. Grosnick; A. Gupta; S. Gupta; W.; Guryn; B. Haag; O. Hajkova; A. Hamed; L-X. Han; J.W. Harris; J.P. Hays-Wehle,; S. Heppelmann; A. Hirsch; G.W. Hoffmann; D.J. Hofman; B. Huang; H.Z. Huang,; T.J. Humanic; L. Huo; G. Igo; W.W. Jacobs; C. Jena; J. Joseph; E.G. Judd; S.; Kabana; K. Kang; J. Kapitan; K. Kauder; H.W. Ke; D. Keane; A. Kechechyan; D.; Kettler; D.P. Kikola; J. Kiryluk; A. Kisiel; V. Kizka; S.R. Klein; D.D.; Koetke; T. Kollegger; J. Konzer; I. Koralt; L. Koroleva; W. Korsch; L.; Kotchenda; P. Kravtsov; K. Krueger; L. Kumar; M.A.C. Lamont; J.M. Landgraf,; S. LaPointe; J. Lauret; A. Lebedev; R. Lednicky; J.H. Lee; W. Leight; M.J.; LeVine; C. Li; L. Li; W. Li; X. Li; X. Li; Y. Li; Z.M. Li; L.M. Lima; M.A.; Lisa; F. Liu; T. Ljubicic; W.J. Llope; R.S. Longacre; Y. Lu; E.V. Lukashov,; X. Luo; G.L. Ma; Y.G. Ma; D.P. Mahapatra; R. Majka; O.I. Mall; R. Manweiler,; S. Margetis; C. Markert; H. Masui; H.S. Matis; D. McDonald; T.S. McShane; A.; Meschanin; R. Milner; N.G. Minaev; S. Mioduszewski; M.K. Mitrovski; Y.; Mohammed; B. Mohanty; M.M. Mondal; B. Morozov; D.A. Morozov; M.G. Munhoz,; M.K. Mustafa; M. Naglis; B.K. Nandi; Md. Nasim; T.K. Nayak; L.V. Nogach; S.B.; Nurushev; G. Odyniec; A. Ogawa; K. Oh; A. Ohlson; V. Okorokov; E.W. Oldag,; R.A.N. Oliveira; D. Olson; M. Pachr; B.S. Page; S.K. Pal; Y. Pandit; Y.; Panebratsev; T. Pawlak; H. Pei; T. Peitzmann; C. Perkins; W. Peryt; P. Pile,; M. Planinic; J. Pluta; D. Plyku; N. Poljak; J. Porter; C.B. Powell; D.; Prindle; C. Pruneau; N.K. Pruthi; P.R. Pujahari; J. Putschke; H. Qiu; R.; Raniwala; S. Raniwala; R.L. Ray; R. Redwine; R. Reed; H.G. Ritter; J.B.; Roberts; O.V. Rogachevskiy; J.L. Romero; L. Ruan; J. Rusnak; N.R. Sahoo; I.; Sakrejda; S. Salur; J. Sandweiss; E. Sangaline; A. Sarkar; J. Schambach; R.P.; Scharenberg; J. Schaub; A.M. Schmah; N. Schmitz; T.R. Schuster; J. Seele; J.; Seger; I. Selyuzhenkov; P. Seyboth; N. Shah; E. Shahaliev; M. Shao; M.; Sharma; S.S. Shi; Q.Y. Shou; E.P. Sichtermann; F. Simon; R.N. Singaraju; M.J.; Skoby; N. Smirnov; D. Solanki; P. Sorensen; U.G. de Souza; H.M. Spinka; B.; Srivastava; T.D.S. Stanislaus; S.G. Steadman; J.R. Stevens; R. Stock; M.; Strikhanov; B. Stringfellow; A.A.P. Suaide; M.C. Suarez; M. Sumbera; X.M.; Sun; Y. Sun; Z. Sun; B. Surrow; D.N. Svirida; T.J.M. Symons; A. Szanto de; Toledo; J. Takahashi; A.H. Tang; Z. Tang; L.H. Tarini; T. Tarnowsky; D.; Thein; J.H. Thomas; J. Tian; A.R. Timmins; D. Tlusty; M. Tokarev; T.A.; Trainor; S. Trentalange; R.E. Tribble; P. Tribedy; B.A. Trzeciak; O.D. Tsai,; T. Ullrich; D.G. Underwood; G. Van Buren; G. van Nieuwenhuizen; J.A.; Vanfossen; Jr.; R. Varma; G.M.S. Vasconcelos; A.N. Vasiliev; F. Videbaek,; Y.P. Viyogi; S. Vokal; M. Wada; M. Walker; F. Wang; G. Wang; H. Wang; J.S.; Wang; Q. Wang; X.L. Wang; Y. Wang; G. Webb; J.C. Webb; G.D. Westfall; C.; Whitten Jr.; H. Wieman; S.W. Wissink; R. Witt; W. Witzke; Y.F. Wu; Z. Xiao,; W. Xie; H. Xu; N. Xu; Q.H. Xu; W. Xu; Y. Xu; Z. Xu; L. Xue; Y. Yang; Y. Yang,; P. Yepes; K. Yip; I-K. Yoo; M. Zawisza; H. Zbroszczyk; W. Zhan; J.B. Zhang,; S. Zhang; W.M. Zhang; X.P. Zhang; Y. Zhang; Z.P. Zhang; F. Zhao; J. Zhao; C.; Zhong; X. Zhu; Y.H. Zhu; Y. Zoulkarneeva

arXiv:1109.4380·nucl-ex·May 30, 2015

Anomalous centrality evolution of two-particle angular correlations from Au-Au collisions at $\sqrt{s_{\rm NN}}$ = 62 and 200 GeV

STAR Collaboration: G. Agakishiev, M.M. Aggarwal, Z. Ahammed, A.V., Alakhverdyants, I. Alekseev, J. Alford, B.D. Anderson, C.D. Anson, D., Arkhipkin, G.S. Averichev, J. Balewski, D.R. Beavis, R. Bellwied, M.J., Betancourt, R.R. Betts, A. Bhasin, A.K. Bhati, H. Bichsel

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TL;DR

This study analyzes two-particle angular correlations in Au-Au collisions at 62 and 200 GeV, revealing a transition in correlation structures that challenges traditional jet quenching and minijet interpretations in dense medium scenarios.

Contribution

It provides detailed measurements of 2D angular correlations and identifies a centrality-dependent transition in correlation structures, questioning existing models of parton scattering and fragmentation.

Findings

01

Correlation structures follow binary-collision scaling until mid-centrality

02

Above a certain centrality, correlations increase rapidly and change shape

03

Results challenge the applicability of minijet and jet quenching models in dense media

Abstract

We present two-dimensional (2D) two-particle angular correlations on relative pseudorapidity $η$ and azimuth $ϕ$ for charged particles from Au-Au collisions at $s_{NN} = 62$ and 200 GeV with transverse momentum $p_{t} \geq 0.15$ GeV/ $c$ , $∣ η ∣ \leq 1$ and $2 π$ azimuth. Observed correlations include a {same-side} (relative azimuth $< π /2$ ) 2D peak, a closely-related away-side azimuth dipole, and an azimuth quadrupole conventionally associated with elliptic flow. The same-side 2D peak and away-side dipole are explained by semihard parton scattering and fragmentation (minijets) in proton-proton and peripheral nucleus-nucleus collisions. Those structures follow N-N binary-collision scaling in Au-Au collisions until mid-centrality where a transition to a qualitatively different centrality trend occurs within a small centrality interval. Above the transition point the…

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