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Probing Majorana Neutrinos in the LHC Era

Probing Majorana Neutrinos in the LHC Era. YongPyong2010 Seoul National University of Tech. Sin Kyu Kang. Outline. Introduction Issues on neutrino masses Probing Majorana neutrino via (1) 0 nbb (2) rare meson decays (3) at the LHC Concluding remarks. Prologue.

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Probing Majorana Neutrinos in the LHC Era

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  1. Probing Majorana Neutrinos in the LHC Era YongPyong2010 Seoul National University of Tech. Sin Kyu Kang

  2. Outline • Introduction • Issues on neutrino masses • Probing Majorana neutrino via • (1) 0nbb • (2) rare meson decays • (3) at the LHC • Concluding remarks

  3. Prologue • Neutrinos aremasslessin the SM • No right-handed ’s  Dirac mass term is not allowed. • Conserves the SU(2)_L gauge symmetry, and only contains • the Higgs doublet (the SM accidently possesses (B-L) • symmetry);  Majorana mass term is forbidden. • Historic Era in Neutrino Physics • Atmospheric nm’s are lost. (SK) (1998) • converted most likely to nt (2000) • Solar ne is converted to either nm or nt(SNO) (2002) • Only the LMA solution left for solar neutrinos (Homestake+Gallium+SK+SNO) (2002) • Reactor anti-ne disappear (2002) and reappear (KamLAND) (2004)

  4. What we learned • Lepton Flavor is not conserved • Neutrinos have tiny mass, not very hierarchical • Neutrinos mix a lot • Very different from quark sectors the first evidence for incompleteness of Minimal Standard Model

  5. Why q23 andq12 are large and close to special values?  Very strong hints at a certain (underlying) flavor symmetry. What we don’t know • absolute mass scale of neutrinos remains an open question. • m1 and m3, which is bigger?  normal or inverted hierarchy? • What is the value of q13? Is it small? how small?  Reactor & accelerator -oscillation experiments can answer, but possibly estimated from a global fit • Is CP violated in neutrino sector? • Neutrinos are Dirac or Majorana?

  6. Interest in Neutrino Mass • Why are physicists interested in neutrino mass ?  Window to high energy physics beyond the SM! • How exactly do we extend it? • Without knowing if neutrinos are Dirac or Majorana, • any attempts to extend the Standard Model are • not successful.

  7. 2 possible types of neutrino masses chiral projection : • Dirac mass terms are invariant under a global symmetry • , but Majorana mass terms are not so. • Thus Dirac mass can be associated with a conserved quantum • number, but Majorana mass violates L number conservation.

  8. A pureDiracmass added into the SM is theoretically • not favored: mainly because it is hard to naturally explain the smallness of mn (violating ‘t Hooft’s naturalness criterion) • Within the context of the SM, gauge invariant operator relevant to the neutrino Majorana mass : • Challenging task is • -- to look for experimental evidence to probe new physics L • -- to distinguish the underlying theoretical models leading to • the effective operator.

  9. If Neutrinos are Majorana • The mass eigenstates are self-conjugate up to a phase. The relative phases between two n’s become observable U = UD X • The Majorana character is only observable for processes • ΔL=2through the mass term that connects interacting • neutrinos with antineutrinos: • AZA(Z+2) + 2e-, μ- + AZ  e+ + A(Z-2), • μ- e+ + 2e-( in 2nd. order)

  10. Neutrino masses, if neutrinos are of Majorana nature, must • have a different origin compared to the masses of charged • leptons and quarks. • A natural theoretical way to understand why 3 -masses • are very small : Seesaw mechanism • Type-I : Right-handed Majorana neutrinos. • Type-II : Higgs triplet. • Type-III : Triplet fermions. ν :

  11. Alternative mechanisms for majorana n mass • Loop Models: Light neutrino masses are radiatively induced. Ma • RPV: Sneutrino gets small VeVs inducing a mixing between n & c.

  12. Fundamental physics and seesaw scale • Forkorder of one, seesaw scale : 1013-14 GeV. no hope of direct observation • For testability, low scale seesaw is desirable • We may keep L free and look for theoretical predictions TeV scale seesaw it may harms naturalness problem

  13. Probing Majorana Neutrinos • Lepton number violation by 2 units plays a crucial role • to probe the Majorana nature of ’s, • The observation of 0 Black Box 0 , • Provides a promising lab. method for determining the • absolute neutrino mass scale that is complementary to • other measurement techniques

  14. Opening Black Box0 • exchange of a virtual light neutrino • Helicity mismatch  mass mechanism • Neutrino  Majorana particle L/R symmetric models R • Exchange of a massive neutrino • Constraints on the model parameters: R

  15. 0nbb decay Light nM exchange ? l111/ ~ 0.06 for mSUSY ~ 1 TeV Heavy particle exchange ?

  16. In the limit of small neutrino masses : the half-life time, ,of the 0nbb decay can be factorized as : : Nuclear matrix element : phase space factor : effective neutrino mass  depends on neutrino mass hierarchy

  17. Estimate by using the best fit values of parameters including uncertainties in Majorana phases Long Baseline

  18. Uncertianties (O.Cremonesi, 05) Large uncertianties in NME About factor of 100 in NME  affect order 2-3 in |< mn>|

  19. Best present bound : Heidel-Moscow Half-life consistent with cosmological bound

  20. Probe of Majorana neutrinos via Rare meson decays (G.Cvetic, C. Dib, SK, C.S.Kim in progress) • Taking mesons in the initial and final state to be • pseudoscalar (M : K, D, Ds, B, Bc) • Not involve the uncertainties from nuclear matrix • elements in 0bnn

  21. transition rates are proportional to

  22. Light neutrino case • In the limit of S-type dominance, the amplitude can • be expressed in a model independent way in terms • of the measured decay constants of the pseudoscalar • mesons in the initial and final state, fM and fM’ • The decay width :  Too small to be measured in future experiments

  23. But, we can get bounds on |<mn>| (ex) for |<mn>| < 0.11 TeV

  24. Intermediate mass scale neutrino case • the most dominant contribution to the process is from the “s-type” diagram because the neutrino propagator is kinematically entirely on-shell

  25. Intermediate mass scale neutrino case • the most dominant contribution to the process is from the “s-type” diagram because the neutrino propagator is kinematically entirely on-shell • the neutrino propagator approximately becomes • For this mass range, • the branching ratio can be substantiallyenhanced

  26. When a certain number of initial M+ is produced and the process is still not detected, the branching ratios allow us to deduce upper bounds on

  27. For

  28. Heavy neutrino case • In this case, both contributions of “s-type” and “t-type” diagrams are rather comparable. • neutrino propagators reduce to -1/(mN)2

  29. Present bounds on for heavy Majorana neutrino • (mN > 100 GeV) are

  30. Probing Majorana Neutrinos at LHC • It is hard to avoid the TeV-scale physics to contribute to flavor-changing effects in general whatever it is, • SUSY, extra dimensions, TeV seesaw, technicolor, Higgsless, little Higgs • In accelerator-based experiments, neutrinos in the final • state are undetectable by the detectors, leading to the • “missing energy”. • So it is desirable to look for charged leptons in the final • state.

  31. Basic process we consider • transition rates are proportional to

  32. Testability at the LHC • Two necessary conditions to test at the LHC: • -- Masses of heavy Majorana n’s must be less than TeV • -- Light-heavy neutrino mixing (i.e., MD/MR) must be large • enough. • LHC signatures of heavy Majorana ’s are essentially • decoupled from masses and mixing parameters of • light Majorana ’s. • Non-unitarity of the light neutrino flavor mixing matrix might lead to observable effects.

  33. L = 2 like-sign dilepton events • Nontrivial limits on heavy Majorana neutrinos can be • derived at the LHC, if the SM backgrounds are small for • a specific final state.

  34. Lepton number violation: like-sign dilepton events at hadron colliders, such as Tevatron (~2 TeV) and LHC (~14 TeV). collider analogue to 0 decay dominant channel N can be produced on resonance Collider Signature

  35. Tevatron LHC Some Results • Cross sections are generally smaller for larger masses of heavy • Majorana neutrinos. [ Han, Zhang (hep-ph/0604064) ] • Signal & background cross sections (in fb) as a function of the • heavy Majorana neutrino mass (in GeV) : • [ Del Aguila et al (hep-ph/0606198) ]

  36. Concluding Remarks • Knowing if neutrinos are Dirac or Majorana is important. • We have discussed three possible ways to probe Majorana • neutrinos. • Hoping that probing Majorana neutrinos via rare meson • decays and collider signature would become more and more • important.

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