Direct determinations of the nucleon and pion σ terms at nearly physical quark masses

Abstract

We present a high statistics study of the pion and nucleon light and strange quark sigma terms using Nf=2 dynamical non-perturbatively improved clover fermions with a range of pion masses down to mπ 150 MeV and several volumes, Lmπ=3.4 up to 6.7, and lattice spacings, a=0.06-0.08 fm, enabling a study of finite volume and discretisation effects for mπ 260 MeV. Systematics are found to be reasonably under control. For the nucleon we obtain σπ N=35(6) MeV and σs=35(12) MeV, or equivalently in terms of the quark fractions, fTu=0.021(4), fTd=0.016(4) and fTs=0.037(13), where the errors include estimates of both the systematic and statistical uncertainties. These values, together with perturbative matching in the heavy quark limit, lead to fTc=0.075(4), fTb=0.072(2) and fTt=0.070(1). In addition, through the use of the (inverse) Feynman-Hellmann theorem our results for σπ N are shown to be consistent with the nucleon masses determined in the analysis. For the pion we implement a method which greatly reduces excited state contamination to the scalar matrix elements from states travelling across the temporal boundary. This enables us to demonstrate the Gell-Mann-Oakes-Renner expectation σπ=mπ/2 over our range of pion masses.