Renormalization-Group Improved Calculation of the B->Xs+gamma Branching Ratio

Abstract

Using results on soft-collinear factorization for inclusive B-meson decay distributions, a systematic study of the partial B Xsγ decay rate with a cut Eγ > E0 on photon energy is performed. For values of E0 below about 1.9 GeV, the rate can be calculated without reference to shape functions using a multi-scale operator product expansion (MSOPE). The transition from the shape-function region to the MSOPE region is studied analytically. The resulting prediction for the B Xsγ branching ratio depends on three large scales: mb, mb, and =mb-2E0. Logarithms associated with these scales are resummed at next-to-next-to-leading logarithmic order. While power corrections in QCD/ turn out to be small, the sensitivity to the scale ≈ 1.1 GeV (for E0≈ 1.8 GeV) introduces significant perturbative uncertainties, which so far have been ignored. The new theoretical prediction for the B Xsγ branching ratio with Eγ 1.8 GeV is Br(B Xsγ)=(3.38-0.42-0.30+0.31+0.32)× 10-4, where the first error is an estimate of perturbative uncertainties and the second one reflects uncertainties in input parameters. With this cut (89-7+6 1)% of all events are contained. The implications of larger theory uncertainties for New Physics searches are briefly explored with the example of the type-II two-Higgs-doublet model, for which the lower bound on the charged-Higgs mass is reduced compared with previous estimates to approximately 200 GeV at 95% confidence level.