Abstract
By solving the Muskhelishvili–Omnès integral equations, the scalar form factors of the semileptonic heavy meson decays Drightarrow pi bar{ell }nu _ell , Drightarrow {bar{K}} bar{ell }nu _ell , {bar{B}}rightarrow pi ell bar{nu }_ell and {bar{B}}_srightarrow K ell bar{nu }_ell are simultaneously studied. As input, we employ unitarized heavy meson–Goldstone boson chiral coupled-channel amplitudes for the energy regions not far from thresholds, while, at high energies, adequate asymptotic conditions are imposed. The scalar form factors are expressed in terms of Omnès matrices multiplied by vector polynomials, which contain some undetermined dispersive subtraction constants. We make use of heavy quark and chiral symmetries to constrain these constants, which are fitted to lattice QCD results both in the charm and the bottom sectors, and in this latter sector to the light-cone sum rule predictions close to q^2=0 as well. We find a good simultaneous description of the scalar form factors for the four semileptonic decay reactions. From this combined fit, and taking advantage that scalar and vector form factors are equal at q^2=0, we obtain |V_{cd}|=0.244pm 0.022, |V_{cs}|=0.945pm 0.041 and |V_{ub}|=(4.3pm 0.7)times 10^{-3} for the involved Cabibbo–Kobayashi–Maskawa (CKM) matrix elements. In addition, we predict the following vector form factors at q^2=0: |f_+^{Drightarrow eta }(0)|=0.01pm 0.05, |f_+^{D_srightarrow K}(0)|=0.50 pm 0.08, |f_+^{D_srightarrow eta }(0)|=0.73pm 0.03 and |f_+^{{bar{B}}rightarrow eta }(0)|=0.82 pm 0.08, which might serve as alternatives to determine the CKM elements when experimental measurements of the corresponding differential decay rates become available. Finally, we predict the different form factors above the q^2-regions accessible in the semileptonic decays, up to moderate energies amenable to be described using the unitarized coupled-channel chiral approach.
Highlights
Exclusive semileptonic decays play a prominent role in the precise determination of the Cabibbo–Kobayashi–Maskawa (CKM) matrix elements, which are important to test the standard model (SM) – any violation of the unitarity of the CKM matrix would reveal new physics beyond the SM (see for instance the review on the CKM mixing parameters by the Particle Data Group (PDG) [1])
We find theoretically sound fits where the LECs10 that determine the rank-one Omnès polynomials describe the lattice QCD (LQCD) data close to qm2 ax, within the range of expected validity of the chiral expansion, while the light-cone sum rules (LCSR) results are reproduced thanks to the non-linear behaviour encoded in the MO matrix (s)
We find a fair description of the LQCD and LCSR results for the Bs0 → K + scalar form factor, while we face some problems for the B 0 → π + decay
Summary
Exclusive semileptonic decays play a prominent role in the precise determination of the Cabibbo–Kobayashi–Maskawa (CKM) matrix elements, which are important to test the standard model (SM) – any violation of the unitarity of the CKM matrix would reveal new physics beyond the SM (see for instance the review on the CKM mixing parameters by the Particle Data Group (PDG) [1]). We construct the MO representations of the scalar form factors, denoted by f0(q2), for the semileptonic D → π and D → Ktransitions, which are related to the unitarized S-wave scattering amplitudes in the Dφ channels with strangeness (S) and isospin (I ) quantum numbers (S, I). These amplitudes are obtained by unitarizing the O( p2) heavymeson chiral perturbative ones [62], with LECs determined from the lattice calculation [56] of the S-wave scattering lengths in several (S, I ) sectors. The heavy-quark scaling rules of the LECs involved in the H φ interactions are discussed in Appendix A, while some further results for b → u form factors, obtained with quadratic MO polynomials, are shown in Appendix B
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