On Compositeness of Ds0*(2317) and its decay to Dsπ0

Abstract

We demonstrate that the Ds0*(2317) can be described as a bound-state pole arising from the coupling between a discrete cs(13P0) state and the DK continuum state in the Lee-Friedrichs model. The elementariness and compositeness of the Ds0*(2317) are determined to be about Z:X≈ 51.1 \%:48.9\%, indicating a nearly equal admixture of compact quark-model state and hadronic molecular components. The decay width of Ds0*(2317)→ Ds+π0 is evaluated within the quark rearrangement framework. The transition cs(13P0)→ Dsπ0 proceeds via the OZI-allowed cs(13P0)-Dsη coupling followed by η-π0 mixing, which serves as the primary source of isospin violation in this channel. The coupling between DK and Dsπ0 is computed in a quark rearrangement model, where the isospin violation effect originates from the mass difference between the D0K+ and D+K0 thresholds. The parameters of the scheme shares the same ones with those of the underlying potential model and only the vacuum production strength is adjusted to reproduce the physical Ds0*(2317) mass. This calculation may shed more insight to the nature of exotic Ds0*(2317) state and its isospin-breaking decay properties.