English

A dilaton-pion mass relation

High Energy Physics - Lattice 2017-07-27 v2 High Energy Physics - Phenomenology High Energy Physics - Theory

Abstract

Recently, Golterman and Shamir presented an effective field theory which is supposed to describe the low-energy physics of the pion and the dilaton in an SU(Nc)SU(N_c) gauge theory with NfN_f Dirac fermions in the fundamental representation. By employing this formulation with a slight but important modification, we derive a relation between the dilaton mass squared~mτ2m_\tau^2, with and without the fermion mass~mm, and the pion mass squared~mπ2m_\pi^2 to the leading order of the chiral logarithm. This is analogous to a similar relation obtained by Matsuzaki and~Yamawaki on the basis of a somewhat different low-energy effective field theory. Our relation reads mτ2=mτ2m=0+KNff^π2mπ2/(2f^τ2)+O(mπ4lnmπ2)m_\tau^2=m_\tau^2|_{m=0}+KN_f\hat{f}_\pi^2m_\pi^2/(2\hat{f}_\tau^2)+O(m_\pi^4\ln m_\pi^2) with~K=9K=9, where f^π\hat{f}_\pi and~f^τ\hat{f}_\tau are decay constants of the pion and the dilaton, respectively. This mass relation differs from the one derived by Matsuzaki and~Yamawaki on the points that K=(3γm)(1+γm)K=(3-\gamma_m)(1+\gamma_m), where γm\gamma_m is the mass anomalous dimension, and the leading chiral logarithm correction is~O(mπ2lnmπ2)O(m_\pi^2\ln m_\pi^2). For~γm1\gamma_m\sim1, the value of the decay constant~f^τ\hat{f}_\tau estimated from our mass relation becomes 50%\sim50\% larger than f^τ\hat{f}_\tau estimated from the relation of Matsuzaki and~Yamawaki.

Keywords

Cite

@article{arxiv.1609.02264,
  title  = {A dilaton-pion mass relation},
  author = {Aya Kasai and Ken-ichi Okumura and Hiroshi Suzuki},
  journal= {arXiv preprint arXiv:1609.02264},
  year   = {2017}
}

Comments

13 pages

R2 v1 2026-06-22T15:43:32.779Z