Techni-dilaton at Conformal Edge

Abstract

Techni-dilaton (TD) was proposed long ago in the technicolor (TC) near criticality/conformality. To reveal the critical behavior of TD, we explicitly compute the nonperturbative contributions to the scale anomaly <θμμ> and to the techni-gluon condensate <Gμ2>, which are generated by the dynamical mass m of the techni-fermions. Our computation is based on the (improved) ladder Schwinger-Dyson equation, with the gauge coupling α replaced by the two-loop running one α(μ) having the Caswell-Banks-Zaks IR fixed point α*: α(μ) α = α* for the IR region m < μ < TC, where TC is the intrinsic scale (analogue of QCD of QCD) relevant to the perturbative scale anomaly. We find that -<θμμ>/m4 const 0 and <Gμ2>/m4 (α/αcr-1)-3/2∞ in the criticality limit m/TC(-π/(α/αcr-1)1/2) 0 (α=α* αcr) ("conformal edge"). Our result precisely reproduces the formal identity <θμμ>=(β(α)/4 α) <Gμ2>, where β(α)=-(2αcr/π) (α/αcr-1)3/2 is the nonperturbative beta function corresponding to the above essential singularity scaling of m/TC. Accordingly, the PCDC implies (MTD/m)2 (FTD/m)2=-4<θμμ>/m4 const 0 at criticality limit, where MTD is the mass of TD and FTD the decay constant of TD. We thus conclude that at criticality limit the TD could become a "true (massless) Nambu-Goldstone boson" MTD/m 0, only when m/FTD 0, namely getting decoupled, as was the case of "holographic TD" of Haba-Matsuzaki-Yamawaki. The decoupled TD can be a candidate of dark matter.