11/21/05Ali Hanks - Journal Club1 Determining Centrality at PHENIX Ali Hanks Journal Club November 21, 2005.

Slides:

Advertisements

Similar presentations

Quark Matter 2006 ( ) Excitation functions of baryon anomaly and freeze-out properties at RHIC-PHENIX Tatsuya Chujo (University of Tsukuba) for.

Advertisements

Di-electron Continuum at PHENIX Yorito Yamaguchi for the PHENIX collaboration CNS, University of Tokyo Rencontres de Moriond - QCD and High Energy Interactions.

A.Litvinenko VBLHEP JINR Определение центральности столкновения ядер с использованием калориметра cпектаторов в эксперименте A.Litvinenko,

J/  in pp, dAu and AuAu Tatia Engelmore Tatia Engelmore Journal Club 5/24.

The Origins of X-Rays. The X-Ray Spectrum The X-Ray Spectrum (Changes in Voltage) The characteristic lines are a result of electrons ejecting orbital.

Cold Nuclear Matter E ﬀ ects on J/ ψ as Constrained by d+Au Measurements at √s NN = 200 GeV in the PHENIX Experiment Matthew Wysocki University of Colorado.

Upsilon production in STAR Pibero Djawotho Indiana University Cyclotron Facility October 12, 2007 DNP 2007.

Detailed study of parton energy loss via measurement of fractional momentum loss of high p T hadrons in heavy ion collisions Takao Sakaguchi Brookhaven.

1 Study of order parameters through fluctuation measurements by the PHENIX detector at RHIC Kensuke Homma for the PHENIX collaboration Hiroshima University.

Mid-Rapidity Hadron Production Studied with the PHENIX detector at RHIC Joakim Nystrand Universitetet i Bergen for the PHENIX Collaboration.

Sourav Tarafdar Banaras Hindu University For the PHENIX Collaboration Hard Probes 2012 Measurement of electrons from Heavy Quarks at PHENIX.

Possible measurements with crystals in NA Test of single crystals for the SPS and LHC beam collimation.

Lecture 5: Electron Scattering, continued... 18/9/2003 1

8/6/2005Tomoaki Nakamura - Hiroshima Univ.1 Tomoaki Nakamura for the PHENIX collaboration Hiroshima University Measurement of event-by-event fluctuations.

Computational Lab in Physics: Final Project Monte Carlo Nuclear Collisions: Glauber Model.

6/25/2007Tomoaki Nakamura - KEK1 Longitudinal density correlations in Au+Au collisions at √s NN = 200 GeV Tomoaki Nakamura (KEK - High Energy Accelerator.

Sevil Salur for STAR Collaboration, Yale University WHAT IS A PENTAQUARK? STAR at RHIC, BNL measures charged particles via Time Projection Chamber. Due.

1 Detector effects on the asymmetry A 1 : The measurability of the polarized structure function g 1 C. Aidala 1,2, A. Deshpande 1,3, V. W. Hughes 1 DESY-PROC ,

High p T  0 Production in p+p, Au+Au, and d+Au Stefan Bathe UC Riverside for the Collaboration Topics in Heavy Ion Collisions McGill University, Montreal,

PHENIX Fig1. Phase diagram Subtracted background Subtracted background Red point : foreground Blue point : background Low-mass vector mesons (ω,ρ,φ) ～

Jornadas LIP 2008 – Pedro Ramalhete. 17 m hadron absorber vertex region 8 MWPCs 4 trigger hodoscopes toroidal magnet dipole magnet hadron absorber targets.

Tomoaki Nakamura - Hiroshima Univ.16/21/2005 Event-by-Event Fluctuations from PHENIX Tomoaki Nakamura for the PHENIX collaboration Hiroshima University.

Single Electron Measurements at RHIC-PHENIX T. Hachiya Hiroshima University For the PHENIX Collaboration.

 4 He(e,e'p)X, April 13 and April 14, 2011, 16 hours Measured P miss at to 1.0 GeV/c, x b = 1.24, Q 2 = 2 (GeV/c) 2 Extension of SRC 2 body data.

J/  production in p+p and 200 GeV as seen by the PHENIX experiment at RHIC Raphaël Granier de Cassagnac LLR – Ecole polytechnique Topics in Heavy-Ions.

Centrality Categorization and its Application to Physics Effects in High-Energy d+A Collisions Javier Orjuela-Koop University of Colorado Boulder For the.

Detail study of the medium created in Au+Au collisions with high p T probes by the PHENIX experiment at RHIC Takao Sakaguchi Brookhaven National Laboratory.

J/psi production in Au+Au and Cu+Cu collisions at RHIC-PHENIX Susumu Oda (Doctor course student) Hamagaki group, CNS, University of Tokyo 2007/08/28 CISS07,

C. Oppedisano for the ALICE Collaboration. 5 Jun 2012 C. Oppedisano 2/10 Centrality in p-A interactions can be defined through the number of collisions.

The centrality dependence of high p T π 0 production in d-Au collisions Abstract Michael Kordell II, Abhijit Majumder Wayne State University, Detroit,

UC Davis June st Rosi Reed Low Energy Test Run Results Rosi Reed University of California at Davis.

Energy Scan of Hadron (  0 ) Suppression and Flow in Au+Au Collisions at PHENIX Norbert Novitzky for PHENIX collaboration University of Jyväskylä, Finland.

Light nuclei production in heavy-ion collisions at RHIC Md. Rihan Haque, for the STAR Collaboration Abstract Light nuclei (anti-nuclei) can be produced.

Azimuthal Anisotropy in U+U Collisions Hui Wang (BNL) and Paul Sorensen (bnl) for the STAR Collaboration Hard Probes 2013, Cape Town, South Africa.

Recent results from PHENIX at RHIC Joakim Nystrand Lund University / University of Bergen The PHENIX experiment Charged particle multiplicity p T spectra.

Latest Charmonium Results from the PHENIX Experiment at RHIC Alexandre Lebedev (Iowa State University) For the PHENIX Collaboration Lake Louise Winter.

Introduction to PHENIX Beam Beam Counter (BBC)

DNP2004M. J. Tannenbaum 1/13 Energy loss of hard scattered partons in Au+Au collisions determined from measurements of  0 and charged hadrons M. J. Tannenbaum.

Oct 6, 2008Amaresh Datta (UMass) 1 Double-Longitudinal Spin Asymmetry in Non-identified Charged Hadron Production at pp Collision at √s = 62.4 GeV at Amaresh.

Charged Particle Multiplicity and Transverse Energy in √s nn = 130 GeV Au+Au Collisions Klaus Reygers University of Münster, Germany for the PHENIX Collaboration.

RPC Design Studies Gabriel Stoicea, NIPNE-HH, Bucharest CBM Software Week GSI-Darmstadt May 10, 2004.

Nucleon-Nucleon collisions. Nucleon-nucleon interaction at low energy Interaction between two nucleons: basic for all of nuclear physics Traditional goal.

Inclusive Measurements of inelastic electron/positron scattering on unpolarized H and D targets at Lara De Nardo for the HERMES COLLABORATION.

First measurements in Pb—Pb collisions at  s NN =2.76 TeV with ALICE at the LHC M. Nicassio (University and INFN Bari) for the ALICE Collaboration Rencontres.

Lecture 07: particle production in AA collisions

Robert Pak (BNL) 2012 RHIC & AGS Annual Users' Meeting 0 Energy Ro Robert Pak for PHENIX Collaboration.

Olena Linnyk Charmonium in heavy ion collisions 16 July 2007.

Kensuke Homma / Hiroshima Univ. from PHENIX collaboration

1 Charged hadron production at large transverse momentum in d+Au and Au+Au collisions at  s=200 GeV Abstract. The suppression of hadron yields with high.

1 Measurements of Leptonic and Photonic Probes in Au+Au Collisions at PHENIX Run-2 Takashi Matsumoto for the PHENIX collaboration at RHIC & AGS Annual.

Itzhak Tserruya Initial Conditions at RHIC: an Experimental Perspective RHIC-INT Workshop LBNL, May31 – June 2, 2001 Itzhak Tserruya Weizmann.

ANGULAR CORRELATION OF NEUTRONS EMITTED FROM DECAY OF GIANT DIPOLE RESONANCE IN ULTRA-PERIPHERAL COLLISIONS AT RHIC In an ultra peripheral collision the.

Diagnosing energy loss: PHENIX results on high-p T hadron spectra Baldo Sahlmüller, University of Münster for the PHENIX collaboration.

Systematic Study of Elliptic Flow at RHIC Maya SHIMOMURA University of Tsukuba ATHIC 2008 University of Tsukuba, Japan October 13-15, 2008.

1 PP Minimum Bias Triggering Simulations Alan Dion Stony Brook University.

Centrality in the Muon Analysis Jane M. Burward-Hoy Physics Review July 17, 2003.

David Silvermyr Lund University for the PHENIX Collaboration Early global event results using the PHENIX Pad Chambers at RHIC.

PHOBOS at RHIC 2000 XIV Symposium of Nuclear Physics Taxco, Mexico January 2001 Edmundo Garcia, University of Maryland.

Centrality, N part & N collision at BRAHMS H. Ito University of Kansas For the BRAHMS Collaboration.

Production, energy loss and elliptic flow of heavy quarks at RHIC and LHC Jan Uphoff with O. Fochler, Z. Xu and C. Greiner Hard Probes 2010, Eilat October.

PHENIX J/  Measurements at  s = 200A GeV Wei Xie UC. RiverSide For PHENIX Collaboration.

Direct Photon v 2 Study in 200 GeV AuAu Collisions at RHIC Guoji Lin (Yale) For STAR Collaboration RHIC & AGS Users’ Meeting, BNL, June 5-9.

Zimanyi-School, Budapest, 03/12/2014 A. Ster, Wigner-RCP, Hungary 1 Total, elastic and inelastic cross sections of high energy pp, pA and  * A reactions.

Kensuke Homma / Hiroshima Univ.1 PHENIX Capabilities for Studying the QCD Critical Point Kensuke Homma / Hiroshima Univ. 9 Jun, RHIC&AGS ANNUAL.

STAR Geometry and Detectors

NUCLEUS-NUCLEUS COLLISION Centrality Determination For NICA/MPD

Tatsuya Chujo for the PHENIX collaboration

Search for the onset of baryon anomaly at RHIC-PHENIX

Kensuke Homma / Hiroshima Univ. from PHENIX collaboration

Presentation transcript:

11/21/05Ali Hanks - Journal Club1 Determining Centrality at PHENIX Ali Hanks Journal Club November 21, 2005

11/21/05Ali Hanks - Journal Club2 Outline  Why is centrality important?  The ZDC detector  The BBC detector  Glauber Model  Negative Binomial Distrbution (NBD)  Putting it all together

11/21/05Ali Hanks - Journal Club3 A few familiar examples  Many things we measure depend on centrality  R AA (Jaimin)  E T and N ch => energy density P.R. C71,

11/21/05Ali Hanks - Journal Club4 The ZDC detector

11/21/05Ali Hanks - Journal Club5 The BBC detector beam pipe Z-direction R-direction Collision point BBC inner ring middle ring outer ring RING ID BB C

11/21/05Ali Hanks - Journal Club6  BBC charge sum is related to number of participant  It has also anti-correlation with ZDC energy sum. Au+Au (Run4)d+Au (Run3)p+p (Run3) participants spectator go into ZDC go into BBC BBC Charge Sum

11/21/05Ali Hanks - Journal Club7 The Glauber Model  Nucleons are distributed according to a density function (e.g. Woods-Saxon)  Nucleons travel in straight lines and are not deflected as they pass through the other nucleus  Nucleons interact according to the inelastic cross section  NN measured in pp collisions, even after interacting  Participants – counts nucleons which interact  Binary collisions – counts collisions nucl-th/ ; (Lectures in the theoretical physics, ed. W. E. Brittin, L. G. Dunham, Interscience, N. Y., 1959, v. 1, p. 315.)

11/21/05Ali Hanks - Journal Club8 The Woods-Saxon density function Electron Scattering Measurements H. DeVries, C.W. De Jager, C. DeVries, 1987

11/21/05Ali Hanks - Journal Club9 Some details Probability of a nucleon-nucleon collision occuring at impact parameter b Probability of finding a nucleon at a certain b and z in the nucleus Probability for a nucleon-nucleon collision occurring when nuclei A and B are at a relative impact parameter b Probability of n collisions occuring where

11/21/05Ali Hanks - Journal Club10 N part & N coll from Glauber So the probability of having  participants in nucleus A is: the probability no nucleons collide = and the average is: So the total averages for a nucleus- nucleus collision at an impact parameter b are:

11/21/05Ali Hanks - Journal Club11 What do we do?  Monte-Carlo Glauber model (MCG)  Generate events with range of impact perameters using Glauber  Divide these events into centrality classes and get a table like this  How do we get back to real data?  Remember the BBC count can be related to N part … but how?

11/21/05Ali Hanks - Journal Club12 NBD  The Negative Binomial Distribution (NBD) is given by:  P(n, ,k) =  (n+k)/(  (k)n!)·(  /k) n /(1+  /k) n+k where (  /  ) 2 = 1/k + 1/  give the width of the distribution  Assuming N hits ~ N part =>  ~ N part  Assuming all hits are uncorrelated => k ~ N part NBD distributions scaled with Glauber probabilities Measured BBC count for fixed number of PC1 hits

11/21/05Ali Hanks - Journal Club13 Fitting the BBC distribution  for N hit  50 the trigger efficiency can assumed equal to 1  P(N hit ) =  (N hit )  Npart NBD(N part, ,k)xMCG(N part )  Use fit to extract NBD parameters:  and k  Now we have a relationship between N part and the actual N nit in the BBC

11/21/05Ali Hanks - Journal Club14 Trigger Efficiency  The last thing is to see how efficiently the BBC is tagging collisions  Integrating this efficiency function gives the total trigger efficiency ~ 94% in Au-Au collisions

11/21/05Ali Hanks - Journal Club15 Centrality Bins  Each color corresponds to a centrality bin  The bins are just percentage of total area under the curve  This gives N hit in the given bin  Use the NBD/MCG fit to relate this to from the Glauber model  Can we do better?  Recall that the efficiency get low for very periferal events (low N hit )  The ZDC can help us

11/21/05Ali Hanks - Journal Club16 BBC vs ZDC  Centrality bins are again determined as a function of the total geometric cross section  Relating these bins to N part is a little tricky now  Use detector response simulations to match data and determine N part  Similar to NBD but complicated by ZDC 0-5% 15-20% 10-15% 0-5% 5-10%

11/21/05Ali Hanks - Journal Club17 Bibliography  S.S. Adler et al, PRC 71, (2005)  Analysis Note 210  Analysis Note 461  P. Shukla, nucl-th/