sPHENIX EMCal discussion

[Anthony Michael Hodges <ahodges21 AT student.gsu.edu>]

Apologies, I failed to mention that the abstract is due August 2nd (this coming Tuesday)!

Thanks! 

-Anthony 

Anthony Hodges (he/him/his)

PhD. Candidate, Georgia State University

High Energy Nuclear Physics

Ahodges21 AT student.gsu.edu

On Jul 29, 2022, at 8:10 PM, Hodges, Anthony <ahodges4 AT illinois.edu> wrote:



Hi everyone, 

One of our undergraduate researchers, Amanda, would like to submit the following abstract for a poster for a Conference Experience for Undergraduates (CEU) program. The poster would be about her work on the position dependent EMCal corrections, which we will present an update on this coming Tuesday at the Calorimeter Calibrations meeting. Please fine the abstract below, and forward any comments you have to me, and I'll relay them to Amanda. 

Many thanks, 

-Anthony

sPHENIX Electromagnetic Calorimeter Block Evaluation

sPHENIX is a detector under construction at the Relativistic Heavy Ion Collider (RHIC) at Brookhaven National Laboratory, and will begin collecting data in February of 2023.  By the collision of heavy nuclei, RHIC is capable of creating a quark-gluon plasma (QGP), a hot, dense state of unconfined quarks and gluons.  Jets, collimated sprays of energetic particles, serve as important probes of the plasma, as they have been modified relative to jets in baseline proton-proton collisions because their parent partons have lost energy to the QGP. In order to provide precision measurements of jets and jet energy loss, sPHENIX has both electromagnetic and hadronic calorimetry at midrapidity. The electromagnetic calorimeter (EMCal) is the innermost calorimeter system and is composed of blocks made of tungsten powder and scintillating fibers. Particles will embed energy into the calorimeter blocks, and the fibers collect that energy in the form of light, which is then read out by a silicon photomultiplier (SiPM).  We report a study of the EMCal’s energy response to single photons measured in an sPHENIX-based GEANT4 simulation.  We have evaluated the average response, as well as how the response varies as a function of where a photon lands in the EMCal.  Inefficiencies in light collection near the edges of the towers are seen and corrected for, using a procedure developed during beam tests of EMCal prototypes.  This poster presents the results of these studies. 

Anthony Hodges, PhD (he/him/his)

Postdoctoral Researcher

High Energy Experimental Nuclear Physics

University of Illinois Urbana-Champaign

_______________________________________________
sPHENIX-EMCal-l mailing list
sPHENIX-EMCal-l AT lists.bnl.gov
https://lists.bnl.gov/mailman/listinfo/sphenix-emcal-l