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Third Harmonic Flow of Charged Particles in Au+Au Collisions at sqrtsNN = 200 GeV

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arxiv 1301.2187 v2 pith:DZYCJVGD submitted 2013-01-10 nucl-ex

Third Harmonic Flow of Charged Particles in Au+Au Collisions at sqrtsNN = 200 GeV

STAR Collaboration: L. Adamczyk , J. K. Adkins , G. Agakishiev , M. M. Aggarwal , Z. Ahammed , I. Alekseev , J. Alford , C. D. Anson
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A. Aparin D. Arkhipkin E. Aschenauer G. S. Averichev J. Balewski A. Banerjee Z. Barnovska 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 A. V. Brandin S. G. Brovko E. Bruna S. B\"ultmann I. Bunzarov T. P. Burton J. Butterworth H. Caines M. Calder\'on de la Barca S\'anchez D. Cebra R. Cendejas M. C. Cervantes P. Chaloupka Z. Chang S. Chattopadhyay H. F. Chen J. H. Chen J. Y. Chen L. Chen J. Cheng M. Cherney A. Chikanian W. Christie P. Chung J. Chwastowski M. J. M. Codrington R. Corliss J. G. Cramer H. J. Crawford X. Cui S. Das A. Davila Leyva L. C. De Silva R. R. Debbe T. G. Dedovich J. Deng R. Derradi de Souza S. Dhamija B. Di Ruzza L. Didenko F. Ding A. Dion P. Djawotho X. Dong J. L. Drachenberg J. E. Draper C. M. Du L. E. Dunkelberger J. C. Dunlop L. G. Efimov M. Elnimr J. Engelage K. S. Engle G. Eppley L. Eun O. Evdokimov R. Fatemi S. Fazio J. Fedorisin R. G. Fersch P. Filip E. Finch Y. Fisyak C. E. Flores C. A. Gagliardi D. R. Gangadharan D. Garand F. Geurts A. Gibson S. Gliske O. G. Grebenyuk D. Grosnick Y. Guo A. Gupta S. Gupta W. Guryn B. Haag O. Hajkova A. Hamed L.-X. Han R. Haque J. W. Harris J. P. Hays-Wehle S. Heppelmann A. Hirsch G. W. Hoffmann D. J. Hofman S. Horvat B. Huang H. Z. Huang P. Huck T. J. Humanic G. Igo W. W. Jacobs C. Jena E. G. Judd S. Kabana K. Kang K. Kauder H. W. Ke D. Keane A. Kechechyan A. Kesich D. P. Kikola J. Kiryluk I. Kisel A. Kisiel D. D. Koetke T. Kollegger J. Konzer I. Koralt W. Korsch L. Kotchenda P. Kravtsov K. Krueger I. Kulakov L. Kumar M. A. C. Lamont J. M. Landgraf K. D. Landry S. LaPointe J. Lauret A. Lebedev R. Lednicky J. H. Lee W. Leight M. J. LeVine C. Li W. Li X. Li Y. Li Z. M. Li L. M. Lima M. A. Lisa F. Liu T. Ljubicic W. J. Llope R. S. Longacre X. Luo A. Luszczak G. L. Ma Y. G. Ma D. M. M. D. Madagodagettige Don D. P. Mahapatra R. Majka S. Margetis C. Markert H. Masui H. S. Matis D. McDonald T. S. McShane S. Mioduszewski M. K. Mitrovski Y. Mohammed B. Mohanty M. M. Mondal M. G. Munhoz M. K. Mustafa M. Naglis B. K. Nandi Md. Nasim T. K. Nayak J. M. Nelson L. V. Nogach J. Novak 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. X. Pan Y. Pandit Y. Panebratsev T. Pawlak B. Pawlik H. Pei C. Perkins W. Peryt P. Pile M. Planinic J. Pluta D. Plyku N. Poljak J. Porter A. M. Poskanzer C. B. Powell C. Pruneau N. K. Pruthi M. Przybycien P. R. Pujahari J. Putschke H. Qiu S. Ramachandran R. Raniwala S. Raniwala C. K. Riley H. G. Ritter J. B. Roberts O. V. Rogachevskiy J. L. Romero J. F. Ross A. Roy L. Ruan J. Rusnak N. R. Sahoo P. K. Sahu I. Sakrejda S. Salur A. Sandacz J. Sandweiss E. Sangaline A. Sarkar J. Schambach R. P. Scharenberg A. M. Schmah B. Schmidke N. Schmitz T. R. Schuster J. Seger P. Seyboth N. Shah E. Shahaliev M. Shao B. Sharma M. Sharma W. Q. Shen S. S. Shi Q. Y. Shou E. P. Sichtermann R. N. Singaraju M. J. Skoby D. Smirnov N. Smirnov D. Solanki P. Sorensen U. G. deSouza H. M. Spinka B. Srivastava T. D. S. Stanislaus 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 J. H. Thomas A. R. Timmins D. Tlusty M. Tokarev S. Trentalange R. E. Tribble P. Tribedy B. A. Trzeciak O. D. Tsai J. Turnau T. Ullrich D. G. Underwood G. Van Buren G. van Nieuwenhuizen J. A. Vanfossen Jr. R. Varma G. M. S. Vasconcelos R. Vertesi F. Videb{\ae}k Y. P. Viyogi S. Vokal S. A. Voloshin A. Vossen 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 H. Wieman S. W. Wissink R. Witt Y. F. Wu Z. Xiao W. Xie K. Xin H. Xu N. Xu Q. H. Xu W. Xu Y. Xu Z. Xu C. Yang Y. Yang P. Yepes L. Yi K. Yip I.-K. Yoo Y. Zawisza H. Zbroszczyk W. Zha J. B. Zhang S. Zhang X. P. Zhang Y. Zhang Z. P. Zhang F. Zhao J. Zhao C. Zhong X. Zhu Y. H. Zhu Y. Zoulkarneeva M. Zyzak
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keywords pseudorapidityflowparticlesanalysischargedcollisionseventfunction
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We report measurements of the third harmonic coefficient of the azimuthal anisotropy, v_3, known as triangular flow. The analysis is for charged particles in Au+Au collisions at sqrtsNN = 200 GeV, based on data from the STAR experiment at the Relativistic Heavy Ion Collider. Two-particle correlations as a function of their pseudorapidity separation are fit with narrow and wide Gaussians. Measurements of triangular flow are extracted from the wide Gaussian, from two-particle cumulants with a pseudorapidity gap, and also from event plane analysis methods with a large pseudorapidity gap between the particles and the event plane. These results are reported as a function of transverse momentum and centrality. A large dependence on the pseudorapidity gap is found. Results are compared with other experiments and model calculations.

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