Analysis of GLAST Balloon Experiment Data Annual meeting of the Physical Society of Japan

1. Analysis of GLAST Balloon Experiment Data • Annual meeting of the Physical Society of Japan • Tsunefumi Mizuno, Hirofumi Mizushima, Akimitsu Ohto, Yasushi Fukazawa, Takashi Ohsugi (Hiroshima University), Tuneyoshi Kamae, Hiroyasu Tajima (SLAC), Masanobu Ozaki (ISAS) • mizuno@hirax6.hepl.hiroshima-u.ac.jp • GLAST LAT/Balloon Experiment(p.2) • Instrument simulator/CR models(p.3) • Data analysis(pp.4-6) • Summary(p.7)

2. GLAST Large Area Telescope/Balloon Experiment Balloon Flight Engineering Model (BFEM): single tower GLAST LAT(20MeV-300GeV) 4X4=16tower eXternal Gamma-ray Target(XGT) Anti Coincidence Detector (ACD) Si-Strip Tracker (TKR) CsI Calorimeter (CAL) Support Structure • To achieve high sensitivity aimed by GLAST, we need to estimate background in orbit accurately. • During the level flight (@38km), we collectedcosmic-ray events (>=100k) to be used for a background database for LAT.

3. Instrument simulator and Cosmic-ray models Proton energy spectrum (from zenith) A Geant4-based Monte-Carlo instrument simulator BESS (magnetic north pole) AMS XGT ACD our model (used in Geant4 Simulation) TKR CAL primary with geomagnetic cutoff and solar modulation @ Palestine, 2001 secondary (atmospheric) 0.01 0.1 1 10 100 GeV alpha Support Structure Pressure Vessel electron/positron • particles with underline are expected in orbit atmospheric gamma muon

4. Count Rate of Each Layer for “Charged Events” Count rate of each layer for “Charged Events” (hit in ACD) • trigger rate (Data) • ~445Hz • simulation total • (our prediction before the flight) • ~350Hz • proton : 145Hz • alpha : 18Hz • e- : 45Hz • e+ : 30Hz • gamma : 50Hz • muon : 62Hz Real Data (level flight) muon gamma e-/e+ alpha proton Count rate observed and simulation prediction agree with each other in ~20% 26 Si layers (13 planes: x-y pair) CAL ACD TKR

5. Angular distribution of “Charged Events” (preliminary) Zenith angles of the straight/single track Straightness of the reconstructed track Data Data Simulation (total) muon muon gamma e-/e+ proton alpha alpha e-/e+ gamma proton 10-6 10-3 1 103 rms (arbitrary unit) horizontal downward cos (theta) straight track • Data and simulation agree with each other in ~20%. • We may need to increase the proton/alpha/muon flux to explain data.

6. Count Rate of Each Layer for Neutral Events Count rate of each layer (no hit in ACD) • trigger rate (Data) • ~55Hz • simulation total • (our prediction before the flight) • ~52Hz • proton : 3.1Hz • alpha : ~0Hz • e- : 6.9Hz • e+ : 3.9Hz • gamma : 35.5Hz • muon : 2.4Hz muon thick Lead converters gamma Real Data (level flight) e-/e+ proton • Overall agreement is good between data and prediction. • Count rate in upper layers are smaller than data.

7. Summary • We performed GLAST Balloon Experiment on August 4th, 2001. • All detector components worked well in high-counting enviroment. • We obtained ~100k Cosmic-ray events to be used as a background database for LAT. • We have developed a Geant4 based instrument simulator and Cosmic-ray flux models. • We have investigated the count rate, straightness of the track and angular dependence of the flux. • Data and simulation prediction agree with each other in ~20%, below uncertainty of CR flux. • Detailed study is underway.