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Contents 1. Introduction 2. Experimental Method 3. Data A nalysis 4. Result 5. Summary

Yoribayashi Yuta Jinnouchi / Shibata Lab. Experimental Observation Of Lepton Pairs Of Invariant Mass Around 95 GeV/c² At The CERN SPS Collider 不変質量 95 GeV/c² 近傍のレプトン対の実験的観測. Contents 1. Introduction 2. Experimental Method 3. Data A nalysis 4. Result 5. Summary.

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Contents 1. Introduction 2. Experimental Method 3. Data A nalysis 4. Result 5. Summary

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  1. Yoribayashi Yuta Jinnouchi/ Shibata Lab Experimental Observation Of Lepton Pairs Of Invariant Mass Around 95 GeV/c² At The CERN SPS Collider不変質量95 GeV/c²近傍のレプトン対の実験的観測 Contents 1. Introduction 2. Experimental Method 3. DataAnalysis 4. Result 5. Summary G. Arnison et al. (UA1 Collaboration). Phys. Lett. B126, 398-410, 1983.

  2. Z0 is the Intermediate Vector Boson predicted by the electroweak theoryas the mediator of weak neutral currents. Electroweak theory is a unified theory of electromagnetic and weak interactions. There are charged intermediate vector bosons W± and a neutral Z0. 1. Introduction ―Intermediate Vector Boson Z0― Z0 e- e- Example of weak neutral current: ν-e scattering expressd in Feynman diagram.

  3. 2. Experimental Method ―Proton-Antiproton Collider ― In quark picture In hadron picture e- proton anti-proton Z0 270 GeV 270 GeV ~45GeV ~45GeV e or μ e+ Proton antiproton collider is suitable for this experiment.

  4. ―Invariant Mass― Before decay Z0 e- After decay θ e+

  5. CERN SPS(Super Proton Synchrotron) collider is located in Geneva, Switzerland. In this experiment, a centre-of-mass energy is The integratedluminosity is ― UA1 Experiment at CERN ― p UA1 SPS anti-p

  6. ―Detector ― • Central tracking chamber • B = 0.7 T • Electromagnetic calorimeter • Hadron calorimeter • Muon chamber beam

  7. ― Event Display ― All tracks from a collision are displayed. All calorimeter hits are displayed. Thresholds are raised to PT > 2GeV/c for charged tracks and ET > 2 GeV for calorimeter hits. Then only a e+e- pair survives these cuts. beam axis e+ beam axis e- 7

  8. 3. Data Analysis • 4 e+e- pairs are observed. • This figure is one of them. • The other events are similar to this. • This is electromagnetic energy deposition at angles >5° with respect to the beam direction. φ: azimuthal angle η: pseudorapidity e- beam axis φ θ e+

  9. 4. Result • This figure shows invariant mass of observed lepton pairs. • From these observations, we deduce the mass for the Z0 particle, mZ0= (95.2 ± 2.5) GeV/c2 Invariant Mass of Lepton pair [Gev/c2] A,B,C,D are e+e-pair events.

  10. Proton-antiproton collider at CERN were used to produce Z0. Quark and antiquark annihilate to Z0 and decay to a lepton pair. UA1 observed this lepton pair. These events fit well the hypothesis that they are produced by the process p + p → Z0 + X e+ + e- μ+ + μ- This paper reports the observation of four e+e- pairs which have the signature of a two-body decay of a particle of mass mZ0 = (95.2 ± 2.5) GeV/c2 . With this discovery, electroweak theory was established. W± bosons had been observed by UA1 5monthes earlier in the same year. 5. Summary

  11. fin

  12. This gas-filled central detector consist of six main modules over 6000 sense wires for detecting electrical signals. The wire are all arranged in planes separated by 20 cm and all wires are parallel to the magnetic field. The electrons produced by the ionization and the passage of these particles can be reconstructed from the electrical signals. The momentum is ― Central Tracking Chamber ―

  13. Weak Boson • There are W and Z boson in weak boson. • W decay to one lepton and one neutrino pair. • Mass of W is • mW= 80.398(25) GeV • Mass of Z is • mZ= 91.1876(21) GeV

  14. Data Selection • Electron trigger • ET > 10 GeV • Muon trigger • |η| ≤ 1.3 ( ~ 30.5º ≤ θ ) • Jet trigger • ET > 20 GeV • in a localized calorimeter. • ET trigger • ET > 50 GeV (|η| ≤ 1.4 )

  15. Two isolated high ET electrons ET > 25 GeV ( PT > 7 GeV/c ) Ehadron <0.8 GeV jets → 1 isolated track ( PT > 25 GeV/c ) 1 track observed fake muon probability ~ 2×10-3 fake e± probability ~ 6×10-3 ↓ negligible heavy flavour jets ( bb, cc ) 2 events with an isolated μ ( PT > 15 GeV/c ) 1 event with an isolated e ( PT > 25 GeV/c ) other jets fake leptons → 10-4 events Onium decay from a new quark σ(QQ) : negligibly small ―Background ―

  16. Data Confidence • Magnetic deflection in 1/p units compared to the inverse of the energy deposited in the electromagnetic calorimeters. • Ideally, all electrons should lie on the 1/E = 1/p line.

  17. Compare with Prediction - Angle of Weinberg- • From their preliminary result, • They parametrize the Z0 mass with the well-known fomula • They find • This is in excellent agreement with the prediction of the minimal model.

  18. Compare with Prediction - Angle of Weinberg-

  19. Weinberg角 • |γ>と|Z0>は|W0>と|B0>を基底に取ったとき以下のように記述される。 • θWはWeinberg角と呼ばれ、実験的に求められる。 • Zボソンの質量は理論的に以下の関係を満たすように固定されている。 • 本論文ではこの関係式より実験結果の整合性を確かめている。

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