Precision for B-meson matrix elements

Abstract

We demonstrate how HQET and the Step Scaling Method for B-physics, pioneered by the Tor Vergata group, can be combined to reach a further improved precision. The observables considered are the mass of the b-quark and the Bs-meson decay constant. The demonstration is carried out in quenched lattice QCD. We start from a small volume, where one can use a standard O(a)-improved relativistic action for the b-quark, and compute two step scaling functions which relate the observables to the large volume ones. In all steps we extrapolate to the continuum limit, separately in HQET and in QCD for masses below mb. The physical point mb is then reached by an interpolation of the continuum results in 1/m. The essential, expected and verified, feature is that the step scaling fuctions have a weak mass-dependence resulting in an easy interpolation to the physical point. With r0=0.5fm and the experimental Bs and K masses as input, we find FBs=191(6)MeV and the renormalization group invariant mass Mb=6.88(10)GeV, translating into mb(mb)=4.42(6)GeV in the MSbar scheme. This approach seems very promising for full QCD.