Abstract
We continue our study of spectroscopy data for the SU(3) gauge theory with eight fundamental fermions, motivated by the effective field theory framework of dilaton chiral perturbation theory (dChPT). At leading order dChPT predicts a constant mass anomalous dimension $\gamma_m$, consistent with the assumed proximity of an infrared fixed point. For the relatively large fermion masses simulated by the LatKMI collaboration, the influence of the infrared fixed point diminishes, and our fits suggest that $\gamma_m$ starts running. Since a complete higher-order analysis is not feasible with presently available data, we adopt a more phenomenological approach. We propose a partial extension to higher orders, which incorporates the running of $\gamma_m$ into the tree-level lagrangian. We find that this extension successfully describes the full fermion-mass range of the LatKMI data, including the pion taste splittings which arise from using staggered fermions in the lattice simulations. We also investigate a more general class of dilaton potentials proposed in the literature, using both the LSD and LatKMI data sets, concluding that these data favor the form predicted by dChPT.
Highlights
Lattice simulations of the SU(3) gauge theory with eight Dirac fermions in the fundamental representation have revealed the existence of a flavor-singlet scalar particle, which, at the fermion masses explored in these simulations, is approximately degenerate with the pions—the NambuGoldstone bosons associated with chiral symmetry breaking [1,2,3,4]
In the window fits to LO dilaton chiral perturbation theory (dChPT), we found that when we include a fit of M2τ =F2π to Eq (2.8d) in our global fit, d3 remains largely undetermined, while all other fit parameters do not change
Our main goal in this paper was to confront the effective field theory (EFT) framework provided by dChPT with the KMI data for the eight-flavor SU(3) gauge theory [4]
Summary
Lattice simulations of the SU(3) gauge theory with eight Dirac fermions in the fundamental representation have revealed the existence of a flavor-singlet scalar particle, which, at the fermion masses explored in these simulations, is approximately degenerate with the pions—the NambuGoldstone bosons associated with chiral symmetry breaking [1,2,3,4]. In a previous paper [33] we applied leading-order (LO) dChPT to numerical data for the eight-flavor SU(3) gauge theory produced in lattice simulations by the LSD Collaboration [3]. This includes the taste splittings, which are qualitatively different from the pattern seen in QCD with staggered fermions Given this success, our goal in this paper is to investigate whether dChPT can be applied to the other major lattice study of the eight-flavor SU(3) gauge theory, by the LatKMI Collaboration [4].4. In Appendix B we investigate the claim of Ref. [32] that Δ-dChPT admits a systematic power counting for any value of Δ and show that this claim is incorrect
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