The possible K K* and D D* bound and resonance states by solving Schrodinger equation

Abstract

The Schrodinger equation with a Yukawa type of potential is solved analytically. When different boundary conditions are taken into account, a series of solutions are indicated as Bessel function, the first kind of Hankel function and the second kind of Hankel function, respectively. Subsequently, the scattering processes of K K* and D D* are investigated. In the K K* sector, the f1(1285) particle is treated as a K K* bound state, therefore, the coupling constant in the K K* Yukawa potential can be fixed according to the binding energy of the f1(1285) particle. Consequently, a K K* resonance state is generated by solving the Schrodinger equation with the outgoing wave condition, which lie at 1417-i18MeV on the complex energy plane. It is reasonable to assume that the K K* resonance state at 1417-i18MeV might correspond to the f1(1420) particle in the review of Particle Data Group(PDG).In the D D* sector, since the X(3872) particle is almost located at the D D* threshold, the binding energy of it equals to zero approximately. Therefore, the coupling constant in the D D* Yukawa potential is determined, which is related to the first zero point of the zero order Bessel function. Similarly to the K K* case, four resonance states are produced as solutions of the Schrodinger equation with the outgoing wave condition. It is assumed that the resonance states at 3885-i1MeV, 4029-i108 MeV, 4328-i191MeV and 4772-i267MeV might be associated with the Zc(3900), the X(3940), the c1(4274) and c1(4685) particles, respectively. It is noted that all solutions are isospin degenerate.