Speaker
Description
Well-bound spherical nuclei can be considered as closed quantum systems that can be described by state-of-the-art versions of the shell model, where nucleons occupy well-localized single-particle states. However, when we move towards the drip line or inject enough excitation energy into the system, the coupling to the continuum and reaction channels becomes more important, forcing the nucleus to behave like a many-body open quantum system. This complex interplay between reaction and structure leads to intriguing phenomena, where weakly bound or unbound systems exhibit features such as halos, particle emission near decay thresholds, and alpha clustering. Inferring the relevant observables to investigate such phenomena requires the use of efficient detection systems for experiments in inverse kinematics. Solenoidal spectrometers are precisely engineered to effectively analyze various reactions resulting in the formation of clustered states. SOLARIS, a next-generation solenoidal spectrometer, offers versatile functionality with its two distinct modes of operation: Si-array and Active Target mode. In this talk, we will discuss the cluster structure of 14C, as explored through an experiment conducted using SOLARIS in Active Target mode with the Active Target Time Projection Chamber (AT-TPC). Some of the states within the two rotational bands (π-bond and σ-bond) of the linear-chain cluster state (LCCS) remain unresolved. We have used resonant scattering of 10Be + 4He as the reaction to explore this nucleus. We present the cross sections, the angular distributions and the spin-parity of several 14C resonances, including states belonging to the rotational bands.
