Is D+sJ(2632) the first radial excitation of Ds*(2112)?
Abstract
We present a quantitative analysis of the D+sJ(2632) observed by SELEX mainly focusing on the assumption that D+sJ(2632) is the first radial excitation of the 1- ground state D*s(2112). By solving the instantaneous Bethe-Salpeter equation, we obtain the mass 2658 15 MeV for the first excited state, which is about 26 MeV heavier than the experimental value 2632 1.7 MeV. By means of PCAC and low-energy theorem we calculate the transition matrix elements and obtain the decay widths: (D+sJ D+sη)=4.07 0.34 MeV, (D+sJ D0K+) ((D+sJ D+K0)=8.9 1.2 MeV, and the ratio (D+sJ D0K+)/(D+sJ D+sη)=2.2 0.2 as well. This ratio is quite different from the SELEX data 0.14 0.06. The summed decay width of those three channels is approximately 21.7 MeV, already larger than the observed bound for the full width (≤ 17 MeV). Furthermore, assuming DsJ+(2632) is 1- state, we also explore the possibility of S-D wave mixing to explain the SELEX observation. Based on our analysis, we suspect that it is too early to conclude that D+sJ(2632) is the first radial excitation of the 1- ground state D*s(2112). More precise measurements of the relative ratios and the total decay width are urgently required especially for S-D wave mixing.
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