Reactor & Accelerator 

1. Reactor & Accelerator  Thanks to Bob McKeown for many of the slides

2. Outline • Reactor Neutrinos The neutrinos Past experiments What we know and what we want to learn • Accelerator Neutrinos The neutrinos Past experiments What we know and what we want to learn Steve Elliott, NPSS 2005

3. neDisappearance Dominant 12Oscillation P(ee) Distance (m) Subdominant 13Oscillation Steve Elliott, NPSS 2005

4. Solar q13 hep-ph/0309130 90, 95, 99% CL Chooz m232 from SK atmospheric Steve Elliott, NPSS 2005

5. Neutrino Oscillation Studies with Nuclear Reactors • ne from n-rich fission products • detection via inverse beta decay (ne+pge++n) • Measure flux and energy spectrum • Improve detectors, reduce background • Variety of distances L= 10m-250km Steve Elliott, NPSS 2005

6. g 2.2 MeV d + p e n n g g 511keV 511keV Detection Signal Coincidence signal: detect • Prompt: e+ annihilation g En=Eprompt+En+0.8 MeV • Delayed: n capture 180 ms capture time Steve Elliott, NPSS 2005

7. Steve Elliott, NPSS 2005

8. Kashiwazaki Takahama Ohi KamLAND uses the entire Japanese nuclear power industry as a long­baseline source Steve Elliott, NPSS 2005

9. Steve Elliott, NPSS 2005

10. Ratio of Measured and Expected e Flux from Reactor Neutrino Experiments Solar n: Dm2 = 5.5x10-5 eV2 sin2 2Q = 0.833 G.Fogli et al., PR D66, 010001-406, (2002) Steve Elliott, NPSS 2005

11. Measurement of Energy Spectrum Steve Elliott, NPSS 2005

12. KamLAND best fit : Dm2 = 7.9 x 10-5 eV2 tan2q = 0.45 KamLAND fixes mass Solar fixes angle Steve Elliott, NPSS 2005

13. New Reactor Proposals Daya Bay, China • ~1.5 km baseline • Deeper/bigger • Near/Far Braidwood, Il Chooz, France Steve Elliott, NPSS 2005

14. horizontal cylinder Detector Design Studies horizontal cylinder spherical Steve Elliott, NPSS 2005

15. Oscillation Formulae for Long-Baseline Neutrinos For anti-neutrinos, the Jcp terms change sign. Steve Elliott, NPSS 2005

16. Long Baseline Physics Goals • Definitive observation of oscillatory behavior in  disappearance mode and precise determination of m223 and 23. • Detection of oscillation e in appearance mode and measurement of 13. • Observe matter effects, hence sign of m223. • Measure cp Steve Elliott, NPSS 2005

17. CP violation and matter effects hep-ph/0306221 Steve Elliott, NPSS 2005

18. T2K Phase I 0.75 MW +SK Phase II 4 MW + HyperK Steve Elliott, NPSS 2005

19. HyperK Steve Elliott, NPSS 2005

20. NOA Use the NUMI beam line from FermiLab. Far detector uses alternate vertical planes of active scintillator with passive wood absorber. Steve Elliott, NPSS 2005

21. Off-Axis Beam • For pions decaying in flight, most neutrinos are forward directed • Neutrino energy is proportional to E • Neutrino energy flattens with angle, however. Allowing one to “choose” an energy by choosing the angle. Steve Elliott, NPSS 2005

22. Far Detector 810 km from target 10-14 km off axis Steve Elliott, NPSS 2005

23. LONG baseline 2500-3000 km Steve Elliott, NPSS 2005

24. The LSND Puzzle and MiniBOONE Steve Elliott, NPSS 2005

25. The Evidence for Neutrino Oscillations Steve Elliott, NPSS 2005

26. Requires a 3rdm2 Steve Elliott, NPSS 2005

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29. Measurement of Oscillation Parameters Steve Elliott, NPSS 2005

30. Typical Muon-Neutrino Event Steve Elliott, NPSS 2005

31. Typical Michel Electron Event Steve Elliott, NPSS 2005

32. Resources • Bob Mckeown APS April 2005 (Tampa) • APS neutrino study on reactors and long baseline experiments. • BNL, T2K and NOA Letters of Intent • Bill Louis Talks Steve Elliott, NPSS 2005