Toward a  +Jet Measurement in STAR Saskia Mioduszewski, for the STAR Collaboration Texas A&M University 1.

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Presentation transcript:

Toward a  +Jet Measurement in STAR Saskia Mioduszewski, for the STAR Collaboration Texas A&M University 1

 -Jet Motivation Photon does not interact strongly, so the trigger energy is more directly connected to the recoil parton energy  initial  Modified Jet Goal: Measure Recoil Jet Energy vs. Initial Energy of Parton, as approximated by trigger- photon energy Ideally studied with fully reconstructed jets on the recoil side of trigger photon More easily studied with azimuthal correlations of charged particles with trigger photon 2

Comparison of Photon- to Hadron-Triggered “Jets” Hadron triggers are surface biased, so recoil parton has (on average) more medium to traverse Recoil parton of photon triggers mostly quark jets, recoil of high-p T  0 are mostly gluon jets (D. de Florian et al., PRD 91, (2015); T. Kaufmann et al., PRD 92, (2015)) – color factor would result in greater energy loss for  0 -triggered jets   initial  Modified Jet 3

 /  0 Discrimination 4  BEMC:- The energy deposition of EM cluster  BSMD:- The η and ϕ positions of EM cluster

 /  0 Discrimination From the hits in the BSMD, construct a quantity “Transverse Shower Profile”: where E cluster is the BEMC cluster energy, e i are the BSMD strip energies, and r i are the strip distances from the center of the cluster The TSP cuts were tuned to select a nearly pure sample of  0 (“  0 rich ”) and a sample with an enhanced fraction of  dir (“  rich ”) 5

Correlation Functions 6  with respect to trigger particle of charged hadrons with |  | < 1 γ rich sample ~60% background in p+p collisions and ~30% background in central Au+Au STAR, arXiv:

Charged-Particle Yields Associated with  0 Triggers On the away side, yields in central Au+Au suppressed relative to yields in p+p On the near side, yields in central Au+Au consistent with yields in p+p z T =p T assoc /p T trig 7 STAR, arXiv: D(z T ) represents the per-trigger associated yields p T trig = GeV/c, p T assoc  1.2 GeV/c

Charged-Particle Yields Associated with  dir Triggers Yields in central Au+Au suppressed relative to yields in p+p where 8 STAR, arXiv: z T =p T assoc /p T trig  p T assoc /p T jet

Hadron Trigger Energy vs. Jet Energy We can estimate the fraction of the parton energy carried by the  0 trigger by summing the additional energy carried by the associated charged particles on the near side Integrating z T times a function fit to the near-side D(z T ) distribution results in Int=0.17  This means that 1/(1+Int)=p T trig /(p T trig +  p T assoc )=85  3% Since the associated particles are charged particles only, we repeat the analysis in PYTHIA, find agreement for charged-particle result, then extend it to include neutral energy: p T trig /p T jet =80  5% 9 STAR, arXiv:

Away-side yields in p+p collisions as a function of “true” z T z T corr =p T assoc /p T jet Near-side D(z T ) measurement for  0 triggers supports PYTHIA estimate that  0 trigger particle carries 80  5% of jet energy for p T trig =12-20 GeV/c Now we can “correct for” p T  0 /p T jet =0.8  z T corr =p T assoc /p T jet for  0 triggers and compare away-side yields for  0 and direct-  triggers directly -- Yields are similar for  0 and  triggers Differences in quark/gluon fragmentation not seen within uncertainties, within z T =(0.1,0.7) 10 STAR, arXiv:

Suppression of jet-like yields on recoil side of  0 triggers vs.  dir triggers Suppression measured via I AA = ratio of per-trigger yields in central Au+Au to minimum-bias p+p collisions Suppression consistent for hadron triggers and photon triggers within uncertainties Suppression appears to be less significant at low z T, low p T assoc No significant differences seen (within errors) due to naïve expectations from effects: 1) difference in surface vs. volume emission and 2) color factor in energy loss Model calculations in agreement with data ZOWW: H. Zhang et al., PRL 103, (2009), X.-F. Chen et al., PRC 81, (2010) Qin: G.-Y. Qin et al., PRC 80, (2009). 11 STAR, arXiv:

I AA as a function of p T assoc Suppression appears to be less significant at low p T assoc 12 STAR, arXiv:

Discussion of Models Models shown in the comparison (ZOWW and Qin) include energy loss of parton propagating through medium with a hydro-evolution of bulk matter; parton shower evolution taken into account analytically In contrast to these models, is the so-called “medium-modified shower” Monte Carlo (YaJEM) where lost energy is redistributed to lower p T jet fragments. In this picture, the in-medium shower is modified, and a suppression at high z T results in an enhancement at lower z T T. Renk, Phys. Rev. C80, (2009). Calculation rises more significantly and at higher z T than our data shows, but here p T trig is lower -- p T assoc  2 GeV/c when I AA =1. 13

Recovery of Energy at Large Angles? Compare away-side yields within  35  vs.  80  No significant effect seen, except in lowest z T bin for  0 triggers PHENIX reported effect for z T <0.4, but p T trig = 5-9 GeV/c  p T assoc < 2 GeV/c (PHENIX, Phys. Rev. Lett. 111, (2013)) 14 STAR, arXiv:

Recovery of Energy at Large Angles? Previous results from STAR Jet- hadron correlations (for two different ranges of jet energies) also indicate that the lost energy is recovered only for p T assoc < 2 GeV/c STAR, Phys.Rev.Lett. 112, (2014) 15

Energy Dependence of Energy Loss Studied via yields associated with direct photon triggers  (E initial ) No dependence of energy loss on E initial is observed for E initial  8-20 GeV 16 STAR, arXiv:

On the Way Toward  -Triggered Jets PYTHIA (v8.185) Study:  -h  yields comparison to STAR p+p data Consistency in results is a good cross-check before studying  -Jet with PYTHIA The same correlations analysis applied to data also applied to PYTHIA events The per-trigger away-side yields are compared via the ratio of simulation to data 17

On the Way Toward  -Triggered Jets Preliminary PYTHIA (v8.185) Study of  -Jet events: Using FastJet anti-k T algorithm with R=0.8 Use “Underlying Event” (UE) region to estimate number of uncorrelated jet candidates Normalization issue – since Recoil side sometimes has an actual correlated jet, there will be fewer R=0.8 uncorrelated jet candidates than in the UE region Recoil region UE Region Trigger 18

Direct-Photon Triggered Jets PYTHIA sim. showing FastJet anti-k T algorithm applied to  -Jet events, R=0.8 Subtracting uncorrelated jet candidates estimated from UE region 19 UE approximately describes first peak (modulo normalization issue) Second peak shifts with p T range of direct-photon triggers

Summary I AA measured via  -triggered vs.  0 -triggered charged- hadron correlations show similar level of suppression for p T trig =12-20 GeV/c, p T assoc >1.2 GeV/c. Suppression is less at low z T (z T <0.2, corresponding to p T assoc <2.4 GeV/c) Comparison with other measurements suggests that recovered energy appears at p T assoc <2 GeV/c, independent of p T trig. Expected difference in  0 triggered vs.  -triggered suppression due to surface vs. volume emission and due to the color factor in energy loss is not seen within our uncertainties  -triggered Jet Reconstruction in STAR coming soon…. 20

Backup Slides 21

TSP from Simulation 22