Abstract
We stress that, although the $D^*$ is very narrow (one hundred of keV), the difference between the full $D^*$ contribution to $B \to \bar{D} \pi \pi$ and its zero width limit, which stems from the resonance tail, is surprisingly large~: several percents. This phenomenon is a general effect which appears when considering the production of particles that are coupled to an intermediate virtual state, stable or not, and it persists whether the width is large or not. The effects of various cuts and of the inclusion of damping factors at the strong and weak vertices are discussed. It is shown how the zero width limit, needed to compare with theoretical expectations, can be extracted. One also evaluates the virtual $D^*_V$ contribution, which comes out roughly as expected from theory, but which is however much more dependent on cuts and uncontrollable "off-shell" effects. We suggest a way to estimate the impact of the damping factors.
Highlights
Values considered for rBW or α are representative of those measured in different experiments, as indicated in the last column of Table III
We have found that to compare expected branching fractions with experiment in B → DÃπ and B → DÃlνl decays, that are always provided from theory in the zerowidth limit, one has to integrate the DÃ → Dπ mass distribution from threshold up to m0cut 1⁄4mDÃ þð9–10Þ MeV=c2 [Eq (19)]; this interval corresponds to more than one hundred times the intrinsic resonance width
The two values are expected to agree at the permil level, independently of effects from damping factors that are usually introduced in decay amplitudes
Summary
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