Jet production at next-to-leading order in p+Au collisions at the RHIC

  • We calculate jet productions in p+Au collisions at the RHIC at next-to-leading order with perturbative QCD. Inclusive jet transverse energy spectrum, dijet invariant mass spectrum, dijet angular distribution, and corresponding nuclear modification factors for the three observables in p+Au collisions at √s=200 GeV are given, where the initial-state cold nuclear matter (CNM) effects are included by taking advantage of four parametrization sets of nuclear parton distribution functions (nPDFs) - EPS, nCTEQ, HKN and DS. We demonstrate that inclusive jet transverse energy (ET) spectrum, dijet invariant mass (MJJ) spectrum with all 4 nPDFs are increased at low ET or MJJ, whereas at high ET or MJJ large deviation of results with different nPDFs is observed. It is found that the dijet angular distributions in p+Au collisions do not vary relative to those in p+p collisions for all 4 nPDFs.
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HE Yun-Cun, ZHANG Ben-Wei and WANG En-Ke. Jet production at next-to-leading order in p+Au collisions at the RHIC[J]. Chinese Physics C, 2012, 36(11): 1077-1081. doi: 10.1088/1674-1137/36/11/007
HE Yun-Cun, ZHANG Ben-Wei and WANG En-Ke. Jet production at next-to-leading order in p+Au collisions at the RHIC[J]. Chinese Physics C, 2012, 36(11): 1077-1081.  doi: 10.1088/1674-1137/36/11/007 shu
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Received: 2012-02-27
Revised: 1900-01-01
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Jet production at next-to-leading order in p+Au collisions at the RHIC

    Corresponding author: HE Yun-Cun,
    Corresponding author: ZHANG Ben-Wei,
    Corresponding author: WANG En-Ke,

Abstract: We calculate jet productions in p+Au collisions at the RHIC at next-to-leading order with perturbative QCD. Inclusive jet transverse energy spectrum, dijet invariant mass spectrum, dijet angular distribution, and corresponding nuclear modification factors for the three observables in p+Au collisions at √s=200 GeV are given, where the initial-state cold nuclear matter (CNM) effects are included by taking advantage of four parametrization sets of nuclear parton distribution functions (nPDFs) - EPS, nCTEQ, HKN and DS. We demonstrate that inclusive jet transverse energy (ET) spectrum, dijet invariant mass (MJJ) spectrum with all 4 nPDFs are increased at low ET or MJJ, whereas at high ET or MJJ large deviation of results with different nPDFs is observed. It is found that the dijet angular distributions in p+Au collisions do not vary relative to those in p+p collisions for all 4 nPDFs.

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