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Understanding of the E391a Detector using K L decay

Understanding of the E391a Detector using K L decay. Ken Sakashita ( Osaka University ) for the E391a collaboration. Overview K L → 3 p 0 analysis K L beam & Detector study Conclusion. Overview(1). CsI Charged Veto Collar counter (CC03) Edge counter. Detector only downstream part.

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Understanding of the E391a Detector using K L decay

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  1. Understanding of the E391a Detector using KL decay Ken Sakashita ( Osaka University ) for the E391a collaboration • Overview • KL → 3p0 analysis • KLbeam & Detector study • Conclusion

  2. Overview(1) • CsI • Charged Veto • Collar counter (CC03) • Edge counter Detector only downstream part • Engineering Run • Detector & KL beam understanding • Data sample vs MonteCarlo • KL 3p0 • Confirm our MC simulation • We need confirmed MC simulation in order to study acceptance and so on.

  3. Overview(2) • Data sample (only 3 hours run used in this study) • Mainly KL 3p0 6g • Energy measured by CsI calorimeter • Only neutral decay mode ( no spectrometer !!) • MonteCarlo Simulation • Input KL beam (avr. P = 4GeV@Detector) • GEANT3 based Detector simulation • Method • Reconstructed KL events • Simple clustering (typically 3x3) • Reconstructed KL 3p0 with good vertex chi square • 0.46 < MKL (GeV) < 0.53 Generated by Beam line Simulation KL momentum (GeV/c)

  4. Data MC KL->3p0 Data vs MC • Invariant mass of 6g# of KL Data/MC = 0.74 • Wrong KL momentum distribution Is the problem due to input KL momentum or detector response ? Compare in 0.5 GeV energy bin

  5. Data MC Data MC KL->3p0 Data vs MC( 0.5GeV EKL bin) • Vertex Z distribution • Sensitive to energy response

  6. KL->3p0 Data vs MC( 0.5GeV EKL bin ) Data MC Data MC • Minimum distance between clusters • Sensitive to energy response

  7. Data MC Data MC KL->3p0 Data vs MC( 0.5GeV EKL bin ) • Cluster Hit Position (distance from the center) • Sensitive to detector response

  8. Data MC Reweighted input KL momentum • MCは、よく detector を再現しているように見える。 • 実験で得られた KL momentum を、 MC の input KL momentum に反映させてみる。 • KL momentum is softer than estimated one. • consistent with results of the Beam survey.

  9. Data MC Data MC KL->3p0 Data vs MC( reweighted ) • Vertex Z match well • Cluster Hit position ( Rij ) still match

  10. Data MC KL->3p0 Data vs MC (reweighted) • PT2 distribution is not consistent with MC. • Beam shape D2( ) is not also consistent with MC. MC does not reproduce KL Beam shape well.

  11. Summary • E391a detector is working well. • We can get good KL pencil beam. • Detector & KL beam understanding using KL->3p0 • KL Beam • Yield Data/MC = 0.74 • Momentum distribution • Softer than estmated distribution • It is consistent with the results of the beam survey • After reweighting Data vs MC match well • Beam shape • MC did not reproduce well. It needs more study. • Detector • More detail study in the next step

  12. 予備OHPs

  13. KL->3p0 Data vs MC( reweighted ) • Cluster Hit position ( Rij ) still match • Minimum distance between clusters still match

  14. KL->3p0 Z reconstruction • Make 3 gamma pairs from 6 clusters • Resonstruct Z vertex by asusuming Mp0 from 2g • Calculate vertex chi square for 15 combinations of 3p0 • Select best combination for KL candidate

  15. Data MC KL->3p0 Data vs MC( reweighted ) • Beam shape ( vertex X,Y )

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