Glueball Spectrum with four light dynamical fermions

Abstract

We perform a calculation of the glueball spectrum for Nf=4 degenerate dynamical fermions with masses corresponding to light pions. We do so by making use of ensembles produced within the framework of maximally twisted fermions by the Extended Twisted Mass Collaboration (ETMC). We obtain masses of states that fall into the irreducible representations of the octahedral group of rotations in combination with the quantum numbers of charge conjugation C and parity P; the above quantum numbers result in 20 distinct irreducible representations. We implement the Generalized Eigenvalue Problem (GEVP) using a basis that consists only of gluonic operators. The purpose of this work is to investigate the effect of light dynamical quarks on the glueball spectrum and how this compares to the statistically more accurate spectrum of SU(3) pure gauge theory. Given that glueball states may have broad widths and thus need to be disentangled from all the relevant mixings, we use large ensembles of the order of ~ O(20 K) configurations. Despite the large ensembles, the statistical uncertainties allow us to extract the masses for only a few irreducible representations; namely A1++, A1-+, E++ as well as T2++. The results for the scalar A1++ representation show that an additional state appears as the lightest state in the scalar A1++ channel of the glueball spectrum, while the next two excited states are consistent with the lightest two states of the pure gauge theory. To further elucidate the nature of this additional state we perform a calculation using Nf=2+1+1 configurations and this demonstrates that it possesses a large quark content. Finally, the ground states of the E++ and T2++ tensor channels and of the A1-+ pseudoscalar channel show, at most, minor effects due to the inclusion of dynamical quarks.