Determination of f+π(0) and Extraction of |Vcd| from Semileptonic D Decays

Abstract

By globally analyzing all existing measured branching fractions for D π e+e decays, partial decay rates in different four momentum transfer-squared q2 bins, as well as products of the decay form factor f+π(q2) and the Cabibbo-Kobayashi-Maskawa (CKM) quark-mixing matrix element |Vcd|, we obtain f+π(0)|Vcd|=0.14280.0019. This product, in conjunction with |Vcd| from a global Standard Model fit, implies a value for the Dπ semileptonic form factor f+π(0)=0.6340.0080.002, which is consistent within error with those calculated in theory based on QCD, but with higher precision than the most accurate f+π(0) LQCD=0.6660.0200.021 calculated in LQCD by a factor of 3.3. Alternately, using this product together with the most accurate form factor calculated in LQCD, we find |Vcd|D π e+e=0.21440.0029 exp 0.0093 LQCD. Combining this |Vcd|D π e+e together with |Vcd|D+μ+μ=0.21600.00490.0014 extracted from both the BESIII and CLEO-c measurements of D+μ+μ decays, we find the most precisely extracted |Vcd| to be |Vcd|=0.21570.0045 up to date, which improves the accuracy of the PDG'2014 value |Vcd| PDG'2014=0.2250.008 by over 70%. Using this |Vcd| together with the PDG'2014 |Vud| and |Vtd|, we check for first column unitarity and find |Vud|2+|Vcd|2+|Vtd|2-1=-0.0040.002, which deviates from unitarity by 2σ. In addition, we find the ratio of f+π(0) and D+ decay constant fD+ to be f+π(0)/fD+=(3.110.08) GeV-1, which can be used to validate LQCD calculations for these two quantities.