The structure of the Yang-Mills spectrum for arbitrary simple gauge
  algebras

A. Cucchieri; A. Feo; A. Maas; A. Salam; A. Szczepaniak; A.C. Aguilar; A.C. Aguilar; A.C. Aguilar; A.P. Szczepaniak; A.P. Szczepaniak; A.P. Szczepaniak; B. Lucini; B. Lucini; B. Svetitsky; B.H. Wellegehausen; C. Ratti; C. Semay; C.J. Morningstar; C.N. Yang; D. Binosi; E. Witten; F. Bissey; F. Buisseret; F. Farchioni; F.G. Fumi; Fabien Buisseret; G. ’t Hooft; G.C. Wick; G.S. Bali; G.S. Bali; G.S. Bali; H. Fritzsch; H.B. Meyer; H.B. Meyer; J. Braun; J. Fuchs; J.F. Cornwell; J.M. Cornwall; J.R. Finger; J.T. Goldman; L. Debbio Del; L. Liptak; M. Cardoso; M. Foster; M. Jacob; M. Pepe; N. Boulanger; N. Brambilla; O. Oliveira; P. Bicudo; P. Guo; P. Guo; R.D. Pisarski; R.L. Jaffe; T.T. Takahashi; V. Mathieu; V. Mathieu; W. Lucha; W.E. Caswell; Y. Chen

slides

The structure of the Yang-Mills spectrum for arbitrary simple gauge algebras

Abstract

The mass spectrum of pure Yang-Mills theory in 3+1 dimensions is discussed for an arbitrary simple gauge algebra within a quasigluon picture. The general structure of the low-lying gluelump and two-quasigluon glueball spectrum is shown to be common to all algebras, while the lightest

C=-

three-quasigluon glueballs only exist when the gauge algebra is A

_{r\geq 2}

, that is in particular

\mathfrak{su}(N\geq3)

. Higher-lying

C=-

glueballs are shown to exist only for the A

_{r\geq2}

, D

_{{\rm odd}-r\geq 4}

and E

_6

gauge algebras. The shape of the static energy between adjoint sources is also discussed assuming the Casimir scaling hypothesis and a funnel form; it appears to be gauge-algebra dependent when at least three sources are considered. As a main result, the present framework's predictions are shown to be consistent with available lattice data in the particular case of an