Composition of low-lying J=32 \,-baryons

Abstract

A Poincar\'e-covariant quark+diquark Faddeev equation is used to develop insights into the structure of the four lightest (I,JP=32,32) baryon multiplets. Whilst these systems can contain isovector-axialvector and isovector-vector diquarks, one may neglect the latter and still arrive at a reliable description. The (32,32+) states are the simpler systems, with features that bear some resemblance to quark model pictures, e.g., their most prominent rest-frame orbital angular momentum component is S-wave and the (1600)32+ may reasonably be viewed as a radial excitation of the (1232)32+. The (32,32-) states are more complex: the (1940)32- expresses little of the character of a radial excitation of the (1700)32-; and whilst the rest-frame wave function of the latter is predominantly P-wave, the leading piece in the (1940)32- wave function is S-wave, in conflict with quark model expectations. Experiments that can test these predictions, such as large momentum transfer resonance electroexcitation, may shed light on the nature of emergent hadron mass.