Transcript Slide 1
Identification of Upsilon Particles Using the Preshower Detector in STAR
Jay Dunkelberger, University of Florida
2007 Texas A&M Cyclotron Institute REU
Advisor: Dr. Saskia Mioduszewski
Quark-Gluon Plasma
Barrel Electromagnetic Calorimeter
Importance of Heavy Quarkonia
•Quarks are the constituents of all hadronic
matter
•Consists of 4800 towers covering the entire azimuthal
range
•In the QGP it is expected that the formation of heavy quarkonia
will be suppressed
•They interact with each other by the strong force
which is mediated by gluons
•Each tower is made up of 21 layers of Pb and scintillator
•This has already been observed at lower energies for J/ψ
particles, however the measurement of J/ψ suppression is
complicated, at RHIC energies, by the competing recombination
of J/ψ particles
•Quarks are confined to exist in either pairs
(mesons) or triplets (baryons)
•Particles interact with the Pb layers and
produce showers which are converted
to light in the scintillator
•At temperatures above 10¹² K
the boundaries of various
hadrons overlap
•84% of electrons shower in the first two
layers of the BEMC as opposed to only
6% of hadrons
An Illustration of
Quark-Gluon Plasma
•Quarks enter a deconfined
state and become a new phase of matter called
the Quark-Gluon Plasma (QGP)
•The upsilon particle has a much larger mass than J/ψ, greatly
reducing the chance of recombination. The relative suppressions
of these particles could be an important sign of the QGP
Detecting Upsilon Particles
•The first two layers of each tower have
their values read out separately and
form the Preshower detector
BEMC Tower
The STAR Experiment
• Located at Brookhaven National Laboratory as
part of the Relativistic Heavy Ion Collider
(RHIC)
Layout of RHIC
Barrel Preshower Detector (BPRS)
The BPRS allows for the reduction of hadronic background by
taking advantage of the fact that electrons generally shower
earlier than hadrons. The BPRS has not yet been used as a
part of STAR’s analysis. We began work on a quality
assurance analysis to include the BPRS in STAR’s run status
table database.
We looked for Υ particles that decayed to a positron and an
electron. We used a combinatorial method to generate oppositesign pairs and created an invariant mass plot. We then used the
same method making like-sign pairs to create a background. We
incorporated the BPRS into our analysis to reduce the number of
hadrons in our calculation. Finally, we subtracted out the
background and looked for an Υ mass peak at ~9.5 GeV/c². This
analysis requires a great deal of statistics and is ongoing.
Reduction of Hadronic Background
Diagram of the STAR Detector
• Au nuclei are accelerated to .99995c and
collide head-on inside the detector, possibly
resulting in the creation of QGP
• STAR has several subsystems (e.g., Time
Projection Chamber, EM Calorimeter) to track the
products of these collisions and look for signs of
the QGP
A comparison of the raw ADC output of the BEMC and BPRS
detectors, which are used in STAR’s status table package. Status
tables are needed to catalogue towers that are giving erroneous data.
A rough analysis of the Preshower detector’s effectiveness. The graphs show
energy loss with distance (dE/dx) as measured in STAR’s Time Projection
Chamber. The right is with a cut on a signal in the Preshower while the left is
without. The red peak results from hadrons while the blue is from electrons.
Integrating these Gaussians showed that the relative yield of electrons
increased by about a factor of two when the Preshower is included.