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Study on the transverse-momentum spectra in 200 GeV d+Au collisions with the Tsallis statistics

  • Department of Modern Physics,University of Science and Technology of China, Hefei 230026,China

Cite this:
https://doi.org/10.3969/j.issn.0253-2778.2014.12.007
  • Received Date: 20 March 2014
  • Accepted Date: 10 June 2014
  • Rev Recd Date: 10 June 2014
  • Publish Date: 30 December 2014
    Abstract

  • Abstract

    The blast-wave model based on the Tsallis statistics (TBW model) was used to study the particle production in 200 GeV d+Au collisions at RHIC. Light hadrons and J/Ψ transverse-momentum spectra at both mid-rapidity and forward/backward rapidity were analyzed. It was found that a non-zero radial flow for light hadrons, indicating a strong cold nuclear matter (CNM) effect in d+Au collisions. J/Ψ shows a finite radial flow at the backward rapidity. This result may imply the onset of initial state color glass condensate (CGC) in the d+Au collision system.

    Abstract

    The blast-wave model based on the Tsallis statistics (TBW model) was used to study the particle production in 200 GeV d+Au collisions at RHIC. Light hadrons and J/Ψ transverse-momentum spectra at both mid-rapidity and forward/backward rapidity were analyzed. It was found that a non-zero radial flow for light hadrons, indicating a strong cold nuclear matter (CNM) effect in d+Au collisions. J/Ψ shows a finite radial flow at the backward rapidity. This result may imply the onset of initial state color glass condensate (CGC) in the d+Au collision system.
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    • References(16)
  • [1]
    Tang Zebo, Xu Yichun, Ruan Lijuan, et al. Spectra and radial flow in relativistic heavy ion collisions with Tsallis statistics in a blast-wave description[J]. Phys Rev C, 2009, 79: 051901.
    [2]
    Tang Zebo, Yi Li, Ruan Lijuan, et al. The statistical origin of constituent-quark scaling in QGP hadronization[J]. Chin Phys Lett, 2013, 30: 031201.
    [3]
    Jiang Kun, Zhu Yinying, Liu Weitao, et al. Onset of radial flow in p+p collisions[DB/OL]. arXiv.org: arXiv:1312.4230.
    [4]
    Adcox K, et al (PHENIX Collaboration). Formation of dense partonic matter in relativistic nucleus-nucleus collisions at RHIC: Experimental evaluation by the PHENIX Collaboration[J]. Nucl Phys A, 2005, 757: 184-283.
    [5]
    Shao M, Yi L, Tang Z, et al. Examination of the species and beam energy dependence of particle spectra using Tsallis statistics[J]. J Phys G, 2010, 37: 085104.
    [6]
    Arsene I, et al (BRAHMS Collaboration). Quark-gluon plasma and color glass condensate at RHIC? The perspective from the BRAHMS experiment[J]. Nucl Phys A, 2005, 757: 1-27.
    [7]
    Ouerdane D. Charged pion and kaon production in central Au+Au collision at SNN=200 GeV[D]. Kopenhagen: Niels Bohr Institute, 2003.
    [8]
    Bearden I G, et al (BRAHMS Collaboration). Nuclear stopping in Au+Au collisions at SNN=200 GeV [J]. Phys Rev Lett, 2004, 93: 102301.
    [9]
    Cronin J W, Frisch H J, Shochet M J, et al. Production of hadrons at large transverse momentum at 200, 300, and 400 GeV[J].Phys Rev D, 1975, 11: 3 105-3 123.
    [10]
    Abelev B, et al (STAR Collaboration). Systematic measurements of identified particle spectra in pp, d+Au and Au+Au collisions from STAR[J]. Phys Rev C, 2009, 79: 034909.
    [11]
    Adams J, et al (STAR Collaboration). Identified hadron spectra at large transverse momentum in p+p and d+Au collisions at SNN=200 GeV[J]. Phys Lett B, 2006, 637:161-169.
    [12]
    Adams J, et al (STAR Collaboration). Pion, kaon, proton and anti-proton transverse momentum distributions from p+p and d+Au collisions at SNN=200 GeV[J]. Phys Lett B, 2005, 616: 8-16.
    [13]
    Abelev B I, et al (STAR Collaboration). Hadronic resonance production in d+Au collisions at 200 GeV at RHIC[J]. Phys Rev C, 2008, 78: 044906.
    [14]
    Adare A, et al (PHENIX Collaboration). Transverse-momentum dependence of the J/Ψ nuclear modification in d+Au collisions at SNN=200 GeV[J]. Phys Rev C, 2013, 87: 034904.
    [15]
    Yang Hongyan. Particle production in d+Au and p+p collisions at SNN=200 GeV[D]. Bergen, Norway: University of Bergen, 2007.
    [16]
    Accardi A, Albacete J L, Anselmino M, et al. Electron ion collider: The next QCD frontier[DB/OL]. arXiv.org: arXiv:1212.1701.
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    [1]
    Tang Zebo, Xu Yichun, Ruan Lijuan, et al. Spectra and radial flow in relativistic heavy ion collisions with Tsallis statistics in a blast-wave description[J]. Phys Rev C, 2009, 79: 051901.
    [2]
    Tang Zebo, Yi Li, Ruan Lijuan, et al. The statistical origin of constituent-quark scaling in QGP hadronization[J]. Chin Phys Lett, 2013, 30: 031201.
    [3]
    Jiang Kun, Zhu Yinying, Liu Weitao, et al. Onset of radial flow in p+p collisions[DB/OL]. arXiv.org: arXiv:1312.4230.
    [4]
    Adcox K, et al (PHENIX Collaboration). Formation of dense partonic matter in relativistic nucleus-nucleus collisions at RHIC: Experimental evaluation by the PHENIX Collaboration[J]. Nucl Phys A, 2005, 757: 184-283.
    [5]
    Shao M, Yi L, Tang Z, et al. Examination of the species and beam energy dependence of particle spectra using Tsallis statistics[J]. J Phys G, 2010, 37: 085104.
    [6]
    Arsene I, et al (BRAHMS Collaboration). Quark-gluon plasma and color glass condensate at RHIC? The perspective from the BRAHMS experiment[J]. Nucl Phys A, 2005, 757: 1-27.
    [7]
    Ouerdane D. Charged pion and kaon production in central Au+Au collision at SNN=200 GeV[D]. Kopenhagen: Niels Bohr Institute, 2003.
    [8]
    Bearden I G, et al (BRAHMS Collaboration). Nuclear stopping in Au+Au collisions at SNN=200 GeV [J]. Phys Rev Lett, 2004, 93: 102301.
    [9]
    Cronin J W, Frisch H J, Shochet M J, et al. Production of hadrons at large transverse momentum at 200, 300, and 400 GeV[J].Phys Rev D, 1975, 11: 3 105-3 123.
    [10]
    Abelev B, et al (STAR Collaboration). Systematic measurements of identified particle spectra in pp, d+Au and Au+Au collisions from STAR[J]. Phys Rev C, 2009, 79: 034909.
    [11]
    Adams J, et al (STAR Collaboration). Identified hadron spectra at large transverse momentum in p+p and d+Au collisions at SNN=200 GeV[J]. Phys Lett B, 2006, 637:161-169.
    [12]
    Adams J, et al (STAR Collaboration). Pion, kaon, proton and anti-proton transverse momentum distributions from p+p and d+Au collisions at SNN=200 GeV[J]. Phys Lett B, 2005, 616: 8-16.
    [13]
    Abelev B I, et al (STAR Collaboration). Hadronic resonance production in d+Au collisions at 200 GeV at RHIC[J]. Phys Rev C, 2008, 78: 044906.
    [14]
    Adare A, et al (PHENIX Collaboration). Transverse-momentum dependence of the J/Ψ nuclear modification in d+Au collisions at SNN=200 GeV[J]. Phys Rev C, 2013, 87: 034904.
    [15]
    Yang Hongyan. Particle production in d+Au and p+p collisions at SNN=200 GeV[D]. Bergen, Norway: University of Bergen, 2007.
    [16]
    Accardi A, Albacete J L, Anselmino M, et al. Electron ion collider: The next QCD frontier[DB/OL]. arXiv.org: arXiv:1212.1701.
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