Comparing RM123 and non-perturbative QCD+QED approaches to the HVP with C-periodic boundary conditions

Abstract

Isospin-breaking corrections to the HVP are among the leading sources of uncertainty in the Standard Model prediction of the muon g-2. In recent work by the RC collaboration, we compute the intermediate window contribution for a flavour non-singlet current using two strategies to include isospin-breaking corrections: the RM123 approach and a fully non-perturbative dynamical QCD+QED simulation. In both computations, we use C-periodic spatial boundary conditions to ensure that locality, gauge invariance, and translational invariance are preserved throughout the calculation. At fixed lattice spacing and volume with Nf =1+2+1 dynamical fermions, and fully including sea-quark effects in both computations, we find that simulating the full QCD+QED distribution yields smaller uncertainties for a fixed statistics. We summarize the comparison of the two approaches and discuss the implications for future lattice QCD+QED computations.