A self-consistent framework of topological amplitude and its SU(N) decomposition

Abstract

We propose a systematic theoretical framework for the topological amplitudes of the heavy meson decays and their SU(N) decomposition. In the framework, the topological amplitudes are expressed in invariant tensors and classified into tree- and penguin-operator-induced diagrams according to which four-quark operators, tree or penguin, being inserted into their effective weak vertexes. By decomposing the four-quark operators into irreducible representations of SU(N) group, one can derive the SU(N) irreducible amplitudes from the tensor form of the topology. Taking the D PP decay (P denoting a pseudoscalar meson) with SU(3)F symmetry as an example, we show our framework in detail. The fact that some topologies are not independent in the SU(3)F limit is explained by group theory. It is found that there are only nine independent topologies in all tree- and penguin-operator-induced diagrams contributing to the D PP decays in the Standard Model. If a large quark-loop diagram is assumed, the large ACP and the very different D0 K+K- and D0 π+π- branching fractions can be explained with a normal U-spin breaking. Moreover, our framework provides a simple and systematic way to analyze the SU(N) breaking effects. As examples, the linear SU(3)F breaking and the high order U-spin breaking in charm decays are re-investigated in our framework, which are consistent with literature. We propose the concepts of splitting and degeneracy of topologies, and use them to describe the charm-less bottom decay. We find SU(3)F analysis for the charm-less B decays is different from the D decays because the charm-quark loop is beyond the SU(3) symmetry and should be investigated in the symmetry breaking chain of SU(4) SU(3).