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A model of flavors

A model of flavors. Jiří Hošek Department of Theoretical Physics NPI Řež (Prague) (Tomáš Brauner and JH, hep-ph /0407339). Plan of presentation. Introductory remarks Strategy: Role of scalars Fermion mass generation Intermediate-boson mass generation Concluding remarks.

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A model of flavors

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  1. A model of flavors Jiří Hošek Department of Theoretical Physics NPI Řež (Prague) (Tomáš Brauner and JH, hep-ph/0407339)

  2. Plan of presentation • Introductory remarks • Strategy: Role of scalars • Fermion mass generation • Intermediate-boson mass generation • Concluding remarks

  3. Introductory remarks Standard model (SM) is the best what in theoretical particle physics we have: In operationally well defined framework it parameterizes and successfully correlates virtually all electroweak phenomena. Objections: 1. QCD is better 2. Neutrino masses are different from zero

  4. Spontaneous mass generation is a theoretical necessity • Hard intermediate boson mass terms ruin directly renormalizability • Hard fermion mass terms ruin indirectly renormalizability • Higgs mechanism is unnatural: quadratic mass renormalization • Too many theoretically arbitrary, phenomenologically vastly different parameters

  5. Attempts to solve disadvantages of SM • SUSY Weakly coupled theory The same Higgs mechanism no quadratic mass renormalization gauge and fermion masses not related whole new parallel world of heavy particles

  6. TECHNICOLOR-LIKE SCENARIOS Strongly coupled theory No quadratic mass renormalization Gauge and fermion masses not related Plenty of heavy techni-hadrons

  7. LITTLE HIGGS Weakly coupled theory No quadratic mass renormalization at “low energy”; at high energy it reappears Gauge and fermion masses not related

  8. DON’T FORGET UNKNOWN

  9. 2. Strategy: Role of scalars • 1. Introduce two distinct complex scalar doublets: S = (S(+) , S(0)) with Y(S) = +1 and ordinary mass squared term in the Lagrangian N = (N(0), N(-)) with Y(N) = -1 and ordinary mass squared term in the Lagrangian • NO SPONTANEOUS BREAKDOWN OF SYMMETRY AT TREE LEVEL

  10. 2. For completeness introduce nf neutrino right-handed SU(2) singlets with zero weak hypercharge: hard Majorana mass term allowed by symmetry

  11. Yukawa couplings of scalars distinguish between otherwise identical fermion families and break down explicitly all unwanted and dangerous inter-family symmetries:

  12. SU(2)Lx U(1)Y gauge symmetry is manifest No fermion mass terms except of MM No gauge-boson mass terms Mass scale of the world fixed by MS and MN This does not imply that the particles corresponding to their massless fields have to stay massless Our model

  13. Breaking SU(2)xU(1) dynamically and non-perturbatively. In perturbation theory the symmetry is preserved order by order. First ASSUME that fermion proper self-energy Σ is generated. Second, FIND IT SELF-CONSISTENTLY. Chirality-changing part of Σ must come out necessarily ultraviolet-finite – fermion mass counter terms strictly forbidden by chiral symmetry

  14. Assumed fermion mass insertions give rise to generically new contributions of the scalar field propagators

  15. Problem reduces to finding the spectrum of the bilinear Lagrangian

  16. Crucial contribution to the scalar-field propagator is

  17. Physically observable are then two real spin-0 particles corresponding to real scalar fields S1 and S2 defined as

  18. The masses and the mixing angle are

  19. The case of the charged scalars is similar: Only particles with the same charge can mix, and they really do:

  20. The masses and the field transformations are

  21. αSN is the phase of μSNand the mixing angle θ is

  22. Splittings μS2 , μN2 and μSN2 of the scalar-particle masses due to yet assumed dynamical fermion mass generation are both natural and important: 1. They come out UV finite due to the large momentum behavior of Σ(p2 ) (see further). 2. They manifest spontaneous breakdown of SU(2)L xU(1)Y symmetry down to U(1)emin the scalar sector. 3. They will be responsible for the UV finiteness of both the fermion and the intermediate vector boson masses.

  23. 3. Fermion mass generation • Chirality-changing fermion proper self-energy Σ(p2) is bona fide given by the UV finite solution of the Schwinger-Dyson equation graphically defined for charged leptons

  24. Explicit form of the equation is not very illuminating. It is, however, easily seen that IF a solution exists it is UV finite:

  25. In order to proceed we are at the moment forced to resort to simplifications. The form of the nonlinearity is kept unchanged: • Neglect fermion mixing (sin 2θ = 0). This, unfortunately, implied neglecting utmost interesting relation between masses of upper and down fermions in doublets. Perform Wick rotation. Do angular integrations. Make Taylor expansion in M21S – M22S (M2 – mean value). For a generic (say e) fermion self-energy in dimensionless variables τ = p2/M2 get

  26. Numerical analysis done so far by Petr Beneš reveals the existence of a solution for large values of β.For electrically charged fermions m = Σ(p2 = m2). • SO FAR ONLY A GENERIC MODEL. It can pretend to phenomenological relevance only after demonstrating strong amplification of fermion masses to small changes of Yukawa couplings.

  27. Generation of neutrino masses is more subtle and requires more work: • Without νR neutrinos would be massless in our model. • With νR the mechanism just described generates UV-finite Dirac Σν. • There is a hard mass term • Due to MM there is a UV-finite left-handed Majorana mass matrix. As a result the model describes 2nf massive Majorana neutrinos with generic sea-saw spectrum

  28. 4. Intermediate-boson mass generation • Dynamically generated fermion proper self-energies Σ(p2) break spontaneously SU(2)L x U(1)Y down to U(1)em. • Consequently, there are just three COMPOSITE Nambu-Goldstone bosons in the spectrum if the gauge interactions are switched off. • When switched on, the W and Z boson should acquire masses. • To determine their values it is necessary to calculate residues at single massless poles of their polarization tensors

  29. ‘Would-be’ NG bosons are visualized as massless poles in proper vertex functions of W and Z bosons as necessary consequences of Ward-Takahashi identities

  30. From the pole terms in Γ we extract the effective two-leg vertices between the gauge and three multi-component ‘would-be’ NG bosons. They are given in terms of the UV-finite loop • As a result the gauge-boson masses are expressed in terms of sum rules

  31. If ΣU and ΣD were degenerate the relation mW2/mZ2cos2ΘW= 1 would be fulfilled. Illustrative analysis with a particular model for Σ shows that the departure from this relation is very small. Knowledge of detailed form of Σ(p2) is indispensable.

  32. 5. Concluding remarks • Genuinely quantum and non-perturbative mechanism of mass generation is rather rigid. • Not yet quantitative; yet strong-coupling. • Quadratic scalar mass renormalization can be avoided. • Relates fermion masses with each other. • Relates fermion masses to the intermediate boson masses. • There is no generic weak-interaction mass scale v = 246 GeV. • Mass scale of the world is fixed by MN, MS and MM. • There should exist four electrically neutral real scalar bosons, and two charged ones. They should be heavy, but not too much (O(106 GeV)).

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