Glueball spectroscopy in lattice QCD using gradient flow

Removing ultraviolet noise from the gauge fields is necessary for glueball spectroscopy in lattice QCD. It is known that the Yang-Mills gradient flow method is an alternative approach instead of link smearing or link fuzzing in various aspects. In this work we study the application of the gradient flow technique to the construction of the extended glueball operators. We examine a simple application of the gradient flow method, which has some problems in glueball mass calculations at large flow time because of its nature of diffusion in space-time. To avoid this problem, the spatial links are evolved by the spatial gradient flow, that is defined to restrict the diffusion to spatial directions only. We test the spatial gradient flow in calculations of glueball two-point functions and Wilson loops as a new smearing method, and then discuss its efficiency in comparison with the original gradient flow method and the conventional method. Furthermore, to demonstrate the feasibility of our proposed method, we determine the masses of the three lowest-lying glueball states, corresponding to the 0++, 2++, and 0-+ glueballs, in the continuum limit in pure Yang-Mills theory.

Automated summary

Removing ultraviolet noise from the gauge fields is crucial for glueball spectroscopy in lattice QCD. The Yang-Mills gradient flow method is explored as an alternative approach for this purpose. The study focuses on the application of the gradient flow technique to the construction of extended glueball operators and proposes using spatial gradient flow to overcome diffusion issues in mass calculations.