S-P-D Mixing in Vector Quarkonia from the Salpeter Equation with Optimized Wave Function Representations

Abstract

This paper proposes a novel mechanism based on the instantaneous Bethe-Salpeter (Salpeter) equation for investigating wave function mixing in vector mesons such as (3770). Conventional theories typically treat (3770) as a 2S-1D mixed state; however, considering only tensor forces or relativistic corrections alone often leads to mixing angles that are too small and inconsistent with experimental data. Phenomenological 2S-1D mixing requires experimental data as input to determine the mixing angles, resulting in limited theoretical studies on states like (1D, 2D) in the absence of experimental data. To more accurately describe S-D mixing and its relativistic effects, this paper systematically compares eight possible relativistic wave function representations (1 to 8) by solving the Salpeter equation and calculates the mass spectra and dileptonic decay widths of charmonium and bottomonium. The study finds that the wave function representation 2 can simultaneously reproduce the experimental data of both charmonium and bottomonium well. Further analysis reveals that, in addition to S-D mixing, the wave functions of vector mesons contain a non-negligible P-wave component, meaning they are S-P-D mixed states. We predict the mixing angles for bottomonium (1D) and (2D) to be (1.78+0.32-0.25) and (5.44+1.10-0.76), with dileptonic decay widths of 2.29+0.86-0.69 eV and 10.5+4.2-3.1 eV, respectively.