Renormalising vector currents in lattice QCD using momentum-subtraction schemes

Abstract

We examine the renormalisation of flavour-diagonal vector currents in lattice QCD with the aim of understanding and quantifying the systematic errors from nonperturbative artefacts associated with the use of intermediate momentum-subtraction schemes. Our study uses the Highly Improved Staggered Quark (HISQ) action on gluon field configurations that include nf=2+1+1 flavours of sea quarks, but our results have applicability to other quark actions. Renormalisation schemes that make use of the exact lattice vector Ward-Takahashi identity for the conserved current also have renormalisation factors, ZV, for nonconserved vector currents that are free of contamination by nonperturbative condensates. We show this by explicit comparison of two such schemes: that of the vector form factor at zero momentum transfer and the RI-SMOM momentum-subtraction scheme. The two determinations of ZV differ only by discretisation effects (for any value of momentum-transfer in the RI-SMOM case). The RI-MOM scheme, although widely used, does not share this property. We show that ZV determined in the standard way in this scheme has O(1\%) nonperturbative contamination that limits its accuracy. Instead we define an RI-MOM ZV from a ratio of local to conserved vector current vertex functions and show that this ZV is a safe one to use in lattice QCD calculations. We also perform a first study of vector current renormalisation with the inclusion of quenched QED effects on the lattice using the RI-SMOM scheme.