The 3$\alpha$ correlations of ground and excited $0^+$ states of $^{12}\mathrm{C}$ within the microscopic cluster model

TL;DR

This paper investigates the cluster structures and $3\alpha$ correlations of $0^+$ states in $^{12}$C, revealing distinct configurations from compact to gas-like states, including the Hoyle state and higher excitations, using a microscopic cluster model.

Contribution

It provides a detailed microscopic analysis of $3\alpha$ correlations in all $0^+$ states of $^{12}$C without assuming $^8$Be, highlighting structural differences among these states.

Findings

The ground state has a compact structure.

The Hoyle state is gas-like with a dominant $0S$ configuration.

Higher $0^+$ states show extended and mixed cluster configurations.

Abstract

The cluster structures of the $0^+$ states in $^{12}\mathrm{C}$, including the ground state, the Hoyle state, and the recently identified $0_3^+$ and $0_4^+$ states, are analyzed to explore the cluster configurations and $3\alpha$ correlations without assuming the existence of $^8\mathrm{Be}$. In particular, the key quantity -- two-cluster overlap amplitudes -- is calculated for the $3\alpha$ clustering channels to reveal the essential features of these $0^+$ states. The results clearly show the distinction between the compact structure of the ground state and the gas-like structures of the excited $0^+$ states. The Hoyle state exhibits the expected gas-like dominant ($0S$) configuration, while the $0_3^+$ state shows a more extended $3\alpha$ clustering structure, which can be viewed as a breathing-like excitation of the Hoyle state, with an additional nodal structure. The $0_4^+$ state is found to have a mixed configuration, featuring a bent-arm-like structure in the $S\otimes S$ channel and an enhanced $2\alpha$ correlation in the $D\otimes D$ channel.