M1 resonance in 208Pb within the self-consistent phonon-coupling model

Abstract

The main goal of the paper is to investigate theoretically the experimentally observed fragmentation of the isovector M1 resonance in 208Pb within a self-consistent model based on an energy-density functional (EDF) of the Skyrme type. This fragmentation (spread of the M1 strength) is not reproduced in a conventional one-particle--one-hole (1p1h) random-phase approximation (RPA) and thus has to be investigated in the framework of more complicated models. However, previously applied models of this type were not self-consistent. In the present work, we use a recently developed renormalized version of the self-consistent time blocking approximation (RenTBA) in which the 1p1h configurations are included on top of the RPA 1p1h configurations. We have determined several sets of the parameters of the modified Skyrme EDF fitted within the RenTBA and RPA and have found the necessary condition of producing the fragmentation of the M1 resonance in 208Pb in our model. We present also the results of the RenTBA and RPA calculations for the first excited states of the natural parity modes in 208Pb obtained with these modified parametrizations.