Crawling technicolor
Abstract
We analyze the Callan-Symanzik equations when scale invariance at a nontrivial infrared (IR) fixed point is realized in the Nambu-Goldstone (NG) mode. As a result, Green's functions at 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 "crawls" towards (but does not pass) in the exact IR limit. The NG mechanism at implies the existence of a massless dilaton , which becomes massive for IR expansions in 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) is proportional to , where is the (positive) slope of the beta function at , is the dilaton decay constant and 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 -dependent deviations from that of the Standard Model. Flavor-changing neutral currents are suppressed if the crawling region 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.
Keywords
Cite
@article{arxiv.1803.08513,
title = {Crawling technicolor},
author = {O. Catà and R. J. Crewther and Lewis C. Tunstall},
journal= {arXiv preprint arXiv:1803.08513},
year = {2019}
}
Comments
42 pages, 4 figures, as in PRD except for the Table of Contents, with Zumino's consistency condition for dilaton Lagrangians highlighted in Sec. 4