Isovector Charges of the Nucleon from 2+1+1-flavor Lattice QCD

Abstract

We present high statistics results for the isovector charges gu-dA, gu-dS and gu-dT of the nucleon. Calculations were carried out on eleven ensembles of gauge configurations generated by the MILC collaboration using highly improved staggered quarks (HISQ) action with 2+1+1 dynamical flavors. These ensembles span four lattice spacings a ≈ 0.06, 0.09, 0.12 and 0.15 fm and light-quark masses corresponding to Mπ ≈ 135, 225 and 315 MeV. Excited-state contamination in the nucleon 3-point correlation functions is controlled by including up to three-states in the spectral decomposition. Remaining systematic uncertainties associated with lattice discretization, lattice volume and light-quark masses are controlled using a simultaneous fit in these three variables. Our final estimates of the isovector charges in the MS scheme at 2 GeV are gAu-d = 1.218(25)(30), gSu-d = 1.022(80)(60) and gTu-d = 0.989(32)(10). The first error includes statistical and all systematic uncertainties except that due to the extrapolation ansatz, which is given by the second error estimate. We provide a detailed comparison with the recent result of gAu-d = 1.271(13) by the CalLat collaboration and argue that our error estimate is more realistic. Combining our estimate for gSu-d with the difference of light quarks masses (md-mu) QCD=2.572(66) MeV given by the MILC/Fermilab/TUMQCD collaboration for 2+1+1-flavor theory, we obtain (MN-MP) QCD = 2.63(27) MeV. We update the low-energy constraints on novel scalar and tensor interactions, εS and εT, at the TeV scale by combining our new estimates for gu-dS and gu-dT with precision low-energy nuclear experiments, and find them comparable to those from the ATLAS and the CMS experiments at the LHC.