Performance of Low Mode Averaging on Twisted-Mass Fermion Ensembles at the physical pion mass point

Abstract

We study the performance of low-mode averaging (LMA) on twisted-mass fermion ensembles at near-physical quark masses, assessing both its theoretical framework and practical cost-effectiveness in modern lattice QCD. In particular, we present a numerical study of light-quark meson and baryon observables. For mesons, we analyse two-point functions, including the vector-vector correlator relevant for the hadronic vacuum polarisation contribution to the muon anomalous magnetic moment, comparing two implementations of LMA: an exact approach based on explicit low modes and an approximate, high-statistics variant using multigrid techniques. For baryons, we restrict to the exact approach and study both two- and three-point functions, quantifying the resulting noise and cost reductions at large Euclidean times. In addition, we compute the eigenvalue density of the massless Wilson operator and determine the renormalised chiral condensate via the Banks-Casher relation, obtaining [3]ΣR=269.5(4.5)~MeV for Nf=2+1+1 isospin-symmetric QCD at a scale 2~GeV in the MS scheme, with an uncertainty dominated by the chiral extrapolation. Additionally, from the pion-mass dependence of ΣR, we extract the scale-independent low-energy constant h1=5.2(1.1).