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This presentation explores the possibility of using neutrino interactions as an alternative approach for producing Bs0 and Bs0 particles, highlighting the advantages and challenges. It also discusses the importance of studying the S-quark and B-quark combination and CP violation. The analysis approach, experimental needs, and potential accelerator options are also discussed.
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Is Bs0 production by neutrino interactions interesting? Presented at the Super-B factory workshop as an alternative approach Nickolas Solomey 21 April 2005
Important because: s-quark and b-quark combination is calculable. CP violation is experimentally possible. A golden mode to study is Bs0 and Bs0 e+e- colliders produce it through Y’’’’’ hadronic production has poor tagging of what was produced. but Physics Interest: Production by neutrino has a possible advantage, but bringing its own difficulties.
Diagram: m-or e- n(m or e) sq meson s-quark qq pair u baryon proton or neutron
Allowed processes: Threshold [GeV] Reaction Charged-current Ds=1 reactions, produce states containing a single strange meson.
Allowed processes: Threshold [GeV] Reaction But a qq pair such as bb or cc can be produced at higher threshold.
Allowed processes: Threshold [GeV] Reaction Possible future experiment at Fermilab aims to study this The Ds=Dq selection rule is enforced, so s-quarks mesons are the only thing allowed with neutrinos.
Antiparticle produced only byassociate production: Reaction The Ds=Dq rule is very powerful. Neutrino and charged lepton used only as a tag, but it is 100%. The neutrino used, i.e. electron type or muon type, does not matter.
Analysis approach: • Lepton charge and type of neutrino beam 100% tags if Bs0 produced. • Lepton track gives location of production. • Bs0 or Bs0 seen at decay point where: • decay identifies what it decayed as Bs0 or Bs0 • momentum of decay products gives momentum of Bs0 to correct for ct flight path. • A b-Baryon confirms bb process.
Experimental needs: • Vertex detector of emulsion or layers of silicon-tracking detectors. • Charged lepton identification of charge. • Decay products: • Good momentum reconstruction to get invariant masses and flight path correction. • Exceptional particle identification. • The higher the neutrino beam energy the better since this will give a longer flight path in the lab-frame. (advantage of Beta beams)
Neutrino Factory with muons, very costly, long term 25+ years away. Modified Fermilab Tevatron with Radioactive heavy ion beams. Argonne Lab may be resource if they get the new RIA. Brookhaven National Laboratory has lots of experience with heavy ions in RHIC, since this experiment does not need a far detector the modification of the RHIC tunnel could be considered. Accelerator:
Problems: • The neutrino rates would have to be high, but this is compatible with the needs of a far detector in the neutrino experiments. • The near experiment would have to be of a high precision for both reconstructing decays and identifying particles.
Conclusion: • A future USA neutrino program may have: • Detailed n oscillation parameters measured. • CP violation search in n Section. • Can b-quark physics be done? • A m-neutrino factory may be very far off in the future, but a beta beam by radioactive heavy ions is possibility. • Take full advantage of other physics that can be done such as study of Bs0 • has advantage of 100% tagged at production. • what are the rates?