Understanding the 1P- and 2S-wave nucleon resonances within the extended Lee-Friedrichs Model

Abstract

We present a unified desciption of the low-lying 1P- and 2S-wave nucleon resonance within the framework of an extended Lee-Friedrichs scheme. By incorporating the coupled-channel dynamics between bare quark-model states and the πN, πΔ and ηN meson-baryon continua, we examine the mass shifts and structural properties of these excited states. We demonstrate that when the model parameters are calibrated to match the 1P-wave spectrum and their widths, the pole associated with the bare 2S state is naturally shifted downward to the mass region of physical Roper resonance--N(1440), thereby offering a dynamical explanation for the long-standing level-inversion problem. An approximate analysis of compositeness and elementariness reveals that the Roper resonance contains a significant meson-baryon continuum states, consistent with the picture of a bare core heavily dressed by meson-baryon cloud. Simultaneously, the pole positions and properties of five 1P-wave resonances--N(1535), N(1650), N(1520), N(1700) and N(1675) are successfully reproduced. Our results highlight the essential role of coupled-channel effects in shaping the nucleon spectrum and provide a consistent microscopic insight into the interplay between internal quark degrees of freedom and external hadronic fields.