Crawling technicolor

Abstract

We analyze the Callan-Symanzik equations when scale invariance at a nontrivial infrared (IR) fixed point αIR is realized in the Nambu-Goldstone (NG) mode. As a result, Green's functions at αIR do not scale in the same way as for the conventional Wigner-Weyl (WW) mode. This allows us to propose a new mechanism for dynamical electroweak symmetry breaking where the running coupling α "crawls" towards (but does not pass) αIR in the exact IR limit. The NG mechanism at αIR implies the existence of a massless dilaton σ, which becomes massive for IR expansions in ε αIR - α and is identified with the Higgs boson. Unlike "dilatons" that are close to a WW-mode fixed point or associated with a Coleman-Weinberg potential, our NG-mode dilaton is genuine and hence naturally light. Its (mass)2 is proportional to ε β'(4+β')Fσ-2 G2vac, where β' is the (positive) slope of the beta function at αIR, Fσ is the dilaton decay constant and G2vac is the technigluon condensate. Our effective field theory for this works because it respects Zumino's consistency condition for dilaton Lagrangians. We find a closed form of the Higgs potential with β'-dependent deviations from that of the Standard Model. Flavor-changing neutral currents are suppressed if the crawling region α αIR includes a sufficiently large range of energies above the TeV scale. In Appendix A, we observe that, contrary to folklore, condensates protect fields from decoupling in the IR limit.