Hermeticity, boost factor and other issues

1. Hermeticity, boost factor and other issues Koji Hara (Nagoya University) BNM2008@Atami

2. Introduction • Studies based on the physics cases are needed to validate and optimize the design of the detector performance and the accelerator. • Boost factor and Hermeticity • How the boost factor affect measurements using Dt and full reconstruction method. • KL detectionefficiency • How important for the mode with missing energy. • Test cases: • BJ/yK0, fK0 tCPV measurement • Btn Brmeasurement Based on our results from Belle data. BNM2008@Atami

3. _ B0 Principle of tCPV measurement CP-side m+ J/y m- (4S) resonance B1 electron (8GeV) KS/L B0 positron (3.5GeV) nm B2 p- bg = 0.425 (Belle) K+ p- Flavor tag and vertex reconstruction Dz ~ 200mm (Belle) m+ • Fully reconstruct one B-meson which decays to CP eigenstate • Tag-side determines its flavor • Proper time (Dt) is measured from decay-vertex difference (Dz) BNM2008@Atami

4. e+ (4S) B- B+ ne n n B++, +e+e B-X Btn Analysis Concepts@Belle • B decays with missing neutrinos lack the kinematic constraints which are used to separate signal events from backgrounds (Mbc and DE) • Reconstruct the decay of the non-signal B (tagging), then look for the signal decay in whatever is left over More than 2 neutrinos appear in B tn decay Tagging side : Fully reconstruct hadronic modes Signal side : Reconstruct particles from t decay BNM2008@Atami

5. BtnSignal Selection • Extra neutral energy in calorimeter EECL - Most powerful variable for separating signal and background -Total calorimeter(ECL) energy from the neutral clusters which are not associated with the tag B Background Btn Signal BNM2008@Atami

6. Hermeticity and boost factor • Large boost factor  better Dt resolution less acceptance in forward region • Small boost factor  worse Dt resolution more acceptance in forward region • Baseline detector design • study of adding super forward detector  K.-F. Chen’s talk BNM2008@Atami

7. Boost factor Dependence • Toy MC results considering Dt resolution and geometrical acceptance. • Geometrical acceptance is assumed to be same as the current Belle detector. - J/yK0 tCPV - fK0 tCPV - Btn BR KEKB can operate worse better BNM2008@Atami

8. KL Veto Efficiency for Btn • Main background in Btn are B decays with KL . • How KL detection efficiency affect the precision of Br(Btn)?  requirement for super KLM e+ B+ ne D0 KL KL BNM2008@Atami

9. KL Veto Efficiency Dependence • Toy MC results for several KL veto efficiencies. • Current is set to 35% • guess by geant simulation + J/yKL data • Q: How can we improve KL detection efficiency of super KLM? worse better KL veto efficiency BNM2008@Atami

10. Summary • Boost factor and Hermeticity • Considering both tCPV and Btn measurements, current KEKB energy (8x3.5) seems the preferable point within the region KEKB can operate. • KL vetoefficiency for Btn • Higher KL veto efficiency is effective for Btn measurement • How can we improve KL detection efficiency of super KLM? • Dependence of other detector performances (PID, tracking&vertexing) must be checked and optimized. • Studies based on the fast simulator are being done. BNM2008@Atami