Systematic analysis of D(s) meson semi-leptonic decays in the covariant light-front quark model

Abstract

The weak decays of the D(s) meson provide a pivotal platform to advance our understanding of the Standard Model (SM) and to explore New Physics (NP). In recent years, experiments have collected a significant amount of data on the D(s) meson decays, particularly from BESIII, which provides substantial support for theoretical research. In this work, we systematically investigate the semi-leptonic decays of D(s) meson to pseudoscalar (P), scalar (S), vector (V), and axial-vector (A) mesons within the framework of the covariant light-front quark model (CLFQM). We calculate the form factors of the transitions D(s) P,S,V,A and the branching ratios of the corresponding semi-leptonic decays, then compare them with experimental data and results from other theoretical models. The form factor values of the transitions D(s) P, V obtained from the CLFQM are consistent with those of other theoretical models and available data in most cases. However, significant discrepancies are found in some specific D(s) S,A transitions, such as D a0(980), a0(1450) and D(s) K1B, compared to other theoretical calculations. The predicted branching ratios for the semi-leptonic decays D P(V) with =e,μ agree well with experimental data and other theoretical results in most decay channels, validating the reliability of the model. However, for some D S(V) decays, tension exists among different theoretical predictions and experimental results. Further clarification of such differences is necessary. Our study provides important insights into the internal structures for some scalar and axial-vector mesons and serves as a theoretical reference for future experiments.

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